[9434] | 1 | /// \ingroup newmat
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| 2 | ///@{
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| 3 |
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| 4 | /// \file fft.cpp
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| 5 | /// \brief Fast Fourier (Carl de Boor) and trig transforms.
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| 6 |
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| 7 |
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| 8 | // Copyright (C) 1991,2,3,4,8: R B Davies
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| 9 |
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| 10 |
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| 11 | #define WANT_MATH
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| 12 | // #define WANT_STREAM
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| 13 |
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| 14 | #include "include.h"
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| 15 |
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| 16 | #include "newmatap.h"
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| 17 |
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| 18 | // #include "newmatio.h"
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| 19 |
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| 20 | #ifdef use_namespace
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| 21 | namespace NEWMAT {
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| 22 | #endif
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| 23 |
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| 24 | #ifdef DO_REPORT
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| 25 | #define REPORT { static ExeCounter ExeCount(__LINE__,19); ++ExeCount; }
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| 26 | #else
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| 27 | #define REPORT {}
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| 28 | #endif
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| 29 |
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| 30 | static void cossin(int n, int d, Real& c, Real& s)
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| 31 | // calculate cos(twopi*n/d) and sin(twopi*n/d)
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| 32 | // minimise roundoff error
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| 33 | {
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| 34 | REPORT
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| 35 | long n4 = n * 4; int sector = (int)floor( (Real)n4 / (Real)d + 0.5 );
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| 36 | n4 -= sector * d;
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| 37 | if (sector < 0) { REPORT sector = 3 - (3 - sector) % 4; }
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| 38 | else { REPORT sector %= 4; }
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| 39 | Real ratio = 1.5707963267948966192 * (Real)n4 / (Real)d;
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| 40 |
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| 41 | switch (sector)
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| 42 | {
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| 43 | case 0: REPORT c = cos(ratio); s = sin(ratio); break;
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| 44 | case 1: REPORT c = -sin(ratio); s = cos(ratio); break;
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| 45 | case 2: REPORT c = -cos(ratio); s = -sin(ratio); break;
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| 46 | case 3: REPORT c = sin(ratio); s = -cos(ratio); break;
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| 47 | }
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| 48 | }
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| 49 |
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| 50 | static void fftstep(ColumnVector& A, ColumnVector& B, ColumnVector& X,
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| 51 | ColumnVector& Y, int after, int now, int before)
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| 52 | {
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| 53 | REPORT
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| 54 | Tracer trace("FFT(step)");
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| 55 | // const Real twopi = 6.2831853071795864769;
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| 56 | const int gamma = after * before; const int delta = now * after;
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| 57 | // const Real angle = twopi / delta; Real temp;
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| 58 | // Real r_omega = cos(angle); Real i_omega = -sin(angle);
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| 59 | Real r_arg = 1.0; Real i_arg = 0.0;
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| 60 | Real* x = X.Store(); Real* y = Y.Store(); // pointers to array storage
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| 61 | const int m = A.Nrows() - gamma;
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| 62 |
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| 63 | for (int j = 0; j < now; j++)
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| 64 | {
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| 65 | Real* a = A.Store(); Real* b = B.Store(); // pointers to array storage
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| 66 | Real* x1 = x; Real* y1 = y; x += after; y += after;
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| 67 | for (int ia = 0; ia < after; ia++)
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| 68 | {
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| 69 | // generate sins & cosines explicitly rather than iteratively
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| 70 | // for more accuracy; but slower
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| 71 | cossin(-(j*after+ia), delta, r_arg, i_arg);
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| 72 |
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| 73 | Real* a1 = a++; Real* b1 = b++; Real* x2 = x1++; Real* y2 = y1++;
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| 74 | if (now==2)
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| 75 | {
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| 76 | REPORT int ib = before;
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| 77 | if (ib) for (;;)
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| 78 | {
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| 79 | REPORT
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| 80 | Real* a2 = m + a1; Real* b2 = m + b1; a1 += after; b1 += after;
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| 81 | Real r_value = *a2; Real i_value = *b2;
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| 82 | *x2 = r_value * r_arg - i_value * i_arg + *(a2-gamma);
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| 83 | *y2 = r_value * i_arg + i_value * r_arg + *(b2-gamma);
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| 84 | if (!(--ib)) break;
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| 85 | x2 += delta; y2 += delta;
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| 86 | }
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| 87 | }
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| 88 | else
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| 89 | {
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| 90 | REPORT int ib = before;
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| 91 | if (ib) for (;;)
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| 92 | {
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| 93 | REPORT
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| 94 | Real* a2 = m + a1; Real* b2 = m + b1; a1 += after; b1 += after;
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| 95 | Real r_value = *a2; Real i_value = *b2;
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| 96 | int in = now-1; while (in--)
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| 97 | {
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| 98 | // it should be possible to make this faster
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| 99 | // hand code for now = 2,3,4,5,8
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| 100 | // use symmetry to halve number of operations
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| 101 | a2 -= gamma; b2 -= gamma; Real temp = r_value;
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| 102 | r_value = r_value * r_arg - i_value * i_arg + *a2;
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| 103 | i_value = temp * i_arg + i_value * r_arg + *b2;
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| 104 | }
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| 105 | *x2 = r_value; *y2 = i_value;
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| 106 | if (!(--ib)) break;
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| 107 | x2 += delta; y2 += delta;
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| 108 | }
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| 109 | }
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| 110 |
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| 111 | // temp = r_arg;
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| 112 | // r_arg = r_arg * r_omega - i_arg * i_omega;
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| 113 | // i_arg = temp * i_omega + i_arg * r_omega;
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| 114 |
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| 115 | }
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| 116 | }
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| 117 | }
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| 118 |
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| 119 |
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| 120 | void FFTI(const ColumnVector& U, const ColumnVector& V,
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| 121 | ColumnVector& X, ColumnVector& Y)
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| 122 | {
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| 123 | // Inverse transform
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| 124 | Tracer trace("FFTI");
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| 125 | REPORT
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| 126 | FFT(U,-V,X,Y);
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| 127 | const Real n = X.Nrows(); X /= n; Y /= (-n);
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| 128 | }
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| 129 |
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| 130 | void RealFFT(const ColumnVector& U, ColumnVector& X, ColumnVector& Y)
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| 131 | {
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| 132 | // Fourier transform of a real series
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| 133 | Tracer trace("RealFFT");
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| 134 | REPORT
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| 135 | const int n = U.Nrows(); // length of arrays
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| 136 | const int n2 = n / 2;
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| 137 | if (n != 2 * n2)
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| 138 | Throw(ProgramException("Vector length not multiple of 2", U));
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| 139 | ColumnVector A(n2), B(n2);
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| 140 | Real* a = A.Store(); Real* b = B.Store(); Real* u = U.Store(); int i = n2;
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| 141 | while (i--) { *a++ = *u++; *b++ = *u++; }
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| 142 | FFT(A,B,A,B);
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| 143 | int n21 = n2 + 1;
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| 144 | X.resize(n21); Y.resize(n21);
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| 145 | i = n2 - 1;
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| 146 | a = A.Store(); b = B.Store(); // first els of A and B
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| 147 | Real* an = a + i; Real* bn = b + i; // last els of A and B
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| 148 | Real* x = X.Store(); Real* y = Y.Store(); // first els of X and Y
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| 149 | Real* xn = x + n2; Real* yn = y + n2; // last els of X and Y
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| 150 |
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| 151 | *x++ = *a + *b; *y++ = 0.0; // first complex element
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| 152 | *xn-- = *a++ - *b++; *yn-- = 0.0; // last complex element
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| 153 |
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| 154 | int j = -1; i = n2/2;
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| 155 | while (i--)
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| 156 | {
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| 157 | Real c,s; cossin(j--,n,c,s);
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| 158 | Real am = *a - *an; Real ap = *a++ + *an--;
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| 159 | Real bm = *b - *bn; Real bp = *b++ + *bn--;
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| 160 | Real samcbp = s * am + c * bp; Real sbpcam = s * bp - c * am;
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| 161 | *x++ = 0.5 * ( ap + samcbp); *y++ = 0.5 * ( bm + sbpcam);
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| 162 | *xn-- = 0.5 * ( ap - samcbp); *yn-- = 0.5 * (-bm + sbpcam);
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| 163 | }
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| 164 | }
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| 165 |
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| 166 | void RealFFTI(const ColumnVector& A, const ColumnVector& B, ColumnVector& U)
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| 167 | {
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| 168 | // inverse of a Fourier transform of a real series
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| 169 | Tracer trace("RealFFTI");
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| 170 | REPORT
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| 171 | const int n21 = A.Nrows(); // length of arrays
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| 172 | if (n21 != B.Nrows() || n21 == 0)
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| 173 | Throw(ProgramException("Vector lengths unequal or zero", A, B));
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| 174 | const int n2 = n21 - 1; const int n = 2 * n2; int i = n2 - 1;
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| 175 |
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| 176 | ColumnVector X(n2), Y(n2);
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| 177 | Real* a = A.Store(); Real* b = B.Store(); // first els of A and B
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| 178 | Real* an = a + n2; Real* bn = b + n2; // last els of A and B
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| 179 | Real* x = X.Store(); Real* y = Y.Store(); // first els of X and Y
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| 180 | Real* xn = x + i; Real* yn = y + i; // last els of X and Y
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| 181 |
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| 182 | Real hn = 0.5 / n2;
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| 183 | *x++ = hn * (*a + *an); *y++ = - hn * (*a - *an);
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| 184 | a++; an--; b++; bn--;
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| 185 | int j = -1; i = n2/2;
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| 186 | while (i--)
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| 187 | {
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| 188 | Real c,s; cossin(j--,n,c,s);
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| 189 | Real am = *a - *an; Real ap = *a++ + *an--;
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| 190 | Real bm = *b - *bn; Real bp = *b++ + *bn--;
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| 191 | Real samcbp = s * am - c * bp; Real sbpcam = s * bp + c * am;
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| 192 | *x++ = hn * ( ap + samcbp); *y++ = - hn * ( bm + sbpcam);
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| 193 | *xn-- = hn * ( ap - samcbp); *yn-- = - hn * (-bm + sbpcam);
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| 194 | }
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| 195 | FFT(X,Y,X,Y); // have done inverting elsewhere
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| 196 | U.resize(n); i = n2;
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| 197 | x = X.Store(); y = Y.Store(); Real* u = U.Store();
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| 198 | while (i--) { *u++ = *x++; *u++ = - *y++; }
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| 199 | }
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| 200 |
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| 201 | void FFT(const ColumnVector& U, const ColumnVector& V,
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| 202 | ColumnVector& X, ColumnVector& Y)
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| 203 | {
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| 204 | // from Carl de Boor (1980), Siam J Sci Stat Comput, 1 173-8
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| 205 | // but first try Sande and Gentleman
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| 206 | Tracer trace("FFT");
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| 207 | REPORT
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| 208 | const int n = U.Nrows(); // length of arrays
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| 209 | if (n != V.Nrows() || n == 0)
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| 210 | Throw(ProgramException("Vector lengths unequal or zero", U, V));
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| 211 | if (n == 1) { REPORT X = U; Y = V; return; }
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| 212 |
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| 213 | // see if we can use the newfft routine
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| 214 | if (!FFT_Controller::OnlyOldFFT && FFT_Controller::CanFactor(n))
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| 215 | {
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| 216 | REPORT
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| 217 | X = U; Y = V;
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| 218 | if ( FFT_Controller::ar_1d_ft(n,X.Store(),Y.Store()) ) return;
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| 219 | }
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| 220 |
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| 221 | ColumnVector B = V;
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| 222 | ColumnVector A = U;
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| 223 | X.resize(n); Y.resize(n);
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| 224 | const int nextmx = 8;
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| 225 | int prime[8] = { 2,3,5,7,11,13,17,19 };
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| 226 | int after = 1; int before = n; int next = 0; bool inzee = true;
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| 227 | int now = 0; int b1; // initialised to keep gnu happy
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| 228 |
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| 229 | do
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| 230 | {
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| 231 | for (;;)
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| 232 | {
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| 233 | if (next < nextmx) { REPORT now = prime[next]; }
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| 234 | b1 = before / now; if (b1 * now == before) { REPORT break; }
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| 235 | next++; now += 2;
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| 236 | }
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| 237 | before = b1;
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| 238 |
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| 239 | if (inzee) { REPORT fftstep(A, B, X, Y, after, now, before); }
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| 240 | else { REPORT fftstep(X, Y, A, B, after, now, before); }
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| 241 |
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| 242 | inzee = !inzee; after *= now;
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| 243 | }
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| 244 | while (before != 1);
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| 245 |
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| 246 | if (inzee) { REPORT A.release(); X = A; B.release(); Y = B; }
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| 247 | }
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| 248 |
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| 249 | // Trigonometric transforms
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| 250 | // see Charles Van Loan (1992) "Computational frameworks for the fast
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| 251 | // Fourier transform" published by SIAM; section 4.4.
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| 252 |
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| 253 | void DCT_II(const ColumnVector& U, ColumnVector& V)
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| 254 | {
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| 255 | // Discrete cosine transform, type II, of a real series
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| 256 | Tracer trace("DCT_II");
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| 257 | REPORT
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| 258 | const int n = U.Nrows(); // length of arrays
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| 259 | const int n2 = n / 2; const int n4 = n * 4;
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| 260 | if (n != 2 * n2)
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| 261 | Throw(ProgramException("Vector length not multiple of 2", U));
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| 262 | ColumnVector A(n);
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| 263 | Real* a = A.Store(); Real* b = a + n; Real* u = U.Store();
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| 264 | int i = n2;
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| 265 | while (i--) { *a++ = *u++; *(--b) = *u++; }
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| 266 | ColumnVector X, Y;
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| 267 | RealFFT(A, X, Y); A.cleanup();
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| 268 | V.resize(n);
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| 269 | Real* x = X.Store(); Real* y = Y.Store();
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| 270 | Real* v = V.Store(); Real* w = v + n;
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| 271 | *v = *x;
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| 272 | int k = 0; i = n2;
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| 273 | while (i--)
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| 274 | {
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| 275 | Real c, s; cossin(++k, n4, c, s);
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| 276 | Real xi = *(++x); Real yi = *(++y);
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| 277 | *(++v) = xi * c + yi * s; *(--w) = xi * s - yi * c;
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| 278 | }
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| 279 | }
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| 280 |
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| 281 | void DCT_II_inverse(const ColumnVector& V, ColumnVector& U)
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| 282 | {
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| 283 | // Inverse of discrete cosine transform, type II
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| 284 | Tracer trace("DCT_II_inverse");
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| 285 | REPORT
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| 286 | const int n = V.Nrows(); // length of array
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| 287 | const int n2 = n / 2; const int n4 = n * 4; const int n21 = n2 + 1;
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| 288 | if (n != 2 * n2)
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| 289 | Throw(ProgramException("Vector length not multiple of 2", V));
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| 290 | ColumnVector X(n21), Y(n21);
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| 291 | Real* x = X.Store(); Real* y = Y.Store();
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| 292 | Real* v = V.Store(); Real* w = v + n;
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| 293 | *x = *v; *y = 0.0;
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| 294 | int i = n2; int k = 0;
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| 295 | while (i--)
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| 296 | {
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| 297 | Real c, s; cossin(++k, n4, c, s);
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| 298 | Real vi = *(++v); Real wi = *(--w);
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| 299 | *(++x) = vi * c + wi * s; *(++y) = vi * s - wi * c;
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| 300 | }
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| 301 | ColumnVector A; RealFFTI(X, Y, A);
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| 302 | X.cleanup(); Y.cleanup(); U.resize(n);
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| 303 | Real* a = A.Store(); Real* b = a + n; Real* u = U.Store();
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| 304 | i = n2;
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| 305 | while (i--) { *u++ = *a++; *u++ = *(--b); }
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| 306 | }
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| 307 |
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| 308 | void DST_II(const ColumnVector& U, ColumnVector& V)
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| 309 | {
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| 310 | // Discrete sine transform, type II, of a real series
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| 311 | Tracer trace("DST_II");
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| 312 | REPORT
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| 313 | const int n = U.Nrows(); // length of arrays
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| 314 | const int n2 = n / 2; const int n4 = n * 4;
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| 315 | if (n != 2 * n2)
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| 316 | Throw(ProgramException("Vector length not multiple of 2", U));
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| 317 | ColumnVector A(n);
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| 318 | Real* a = A.Store(); Real* b = a + n; Real* u = U.Store();
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| 319 | int i = n2;
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| 320 | while (i--) { *a++ = *u++; *(--b) = -(*u++); }
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| 321 | ColumnVector X, Y;
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| 322 | RealFFT(A, X, Y); A.cleanup();
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| 323 | V.resize(n);
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| 324 | Real* x = X.Store(); Real* y = Y.Store();
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| 325 | Real* v = V.Store(); Real* w = v + n;
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| 326 | *(--w) = *x;
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| 327 | int k = 0; i = n2;
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| 328 | while (i--)
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| 329 | {
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| 330 | Real c, s; cossin(++k, n4, c, s);
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| 331 | Real xi = *(++x); Real yi = *(++y);
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| 332 | *v++ = xi * s - yi * c; *(--w) = xi * c + yi * s;
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| 333 | }
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| 334 | }
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| 335 |
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| 336 | void DST_II_inverse(const ColumnVector& V, ColumnVector& U)
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| 337 | {
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| 338 | // Inverse of discrete sine transform, type II
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| 339 | Tracer trace("DST_II_inverse");
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| 340 | REPORT
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| 341 | const int n = V.Nrows(); // length of array
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| 342 | const int n2 = n / 2; const int n4 = n * 4; const int n21 = n2 + 1;
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| 343 | if (n != 2 * n2)
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| 344 | Throw(ProgramException("Vector length not multiple of 2", V));
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| 345 | ColumnVector X(n21), Y(n21);
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| 346 | Real* x = X.Store(); Real* y = Y.Store();
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| 347 | Real* v = V.Store(); Real* w = v + n;
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| 348 | *x = *(--w); *y = 0.0;
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| 349 | int i = n2; int k = 0;
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| 350 | while (i--)
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| 351 | {
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| 352 | Real c, s; cossin(++k, n4, c, s);
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| 353 | Real vi = *v++; Real wi = *(--w);
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| 354 | *(++x) = vi * s + wi * c; *(++y) = - vi * c + wi * s;
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| 355 | }
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| 356 | ColumnVector A; RealFFTI(X, Y, A);
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| 357 | X.cleanup(); Y.cleanup(); U.resize(n);
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| 358 | Real* a = A.Store(); Real* b = a + n; Real* u = U.Store();
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| 359 | i = n2;
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| 360 | while (i--) { *u++ = *a++; *u++ = -(*(--b)); }
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| 361 | }
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| 362 |
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| 363 | void DCT_inverse(const ColumnVector& V, ColumnVector& U)
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| 364 | {
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| 365 | // Inverse of discrete cosine transform, type I
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| 366 | Tracer trace("DCT_inverse");
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| 367 | REPORT
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| 368 | const int n = V.Nrows()-1; // length of transform
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| 369 | const int n2 = n / 2; const int n21 = n2 + 1;
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| 370 | if (n != 2 * n2)
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| 371 | Throw(ProgramException("Vector length not multiple of 2", V));
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| 372 | ColumnVector X(n21), Y(n21);
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| 373 | Real* x = X.Store(); Real* y = Y.Store(); Real* v = V.Store();
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| 374 | Real vi = *v++; *x++ = vi; *y++ = 0.0;
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| 375 | Real sum1 = vi / 2.0; Real sum2 = sum1; vi = *v++;
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| 376 | int i = n2-1;
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| 377 | while (i--)
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| 378 | {
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| 379 | Real vi2 = *v++; sum1 += vi2 + vi; sum2 += vi2 - vi;
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| 380 | *x++ = vi2; vi2 = *v++; *y++ = vi - vi2; vi = vi2;
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| 381 | }
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| 382 | sum1 += vi; sum2 -= vi;
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| 383 | vi = *v; *x = vi; *y = 0.0; vi /= 2.0; sum1 += vi; sum2 += vi;
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| 384 | ColumnVector A; RealFFTI(X, Y, A);
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| 385 | X.cleanup(); Y.cleanup(); U.resize(n+1);
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| 386 | Real* a = A.Store(); Real* b = a + n; Real* u = U.Store(); v = u + n;
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| 387 | i = n2; int k = 0; *u++ = sum1 / n2; *v-- = sum2 / n2;
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| 388 | while (i--)
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| 389 | {
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| 390 | Real s = sin(1.5707963267948966192 * (++k) / n2);
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| 391 | Real ai = *(++a); Real bi = *(--b);
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| 392 | Real bz = (ai - bi) / 4 / s; Real az = (ai + bi) / 2;
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| 393 | *u++ = az - bz; *v-- = az + bz;
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| 394 | }
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| 395 | }
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| 396 |
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| 397 | void DCT(const ColumnVector& U, ColumnVector& V)
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| 398 | {
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| 399 | // Discrete cosine transform, type I
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| 400 | Tracer trace("DCT");
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| 401 | REPORT
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| 402 | DCT_inverse(U, V);
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| 403 | V *= (V.Nrows()-1)/2;
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| 404 | }
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| 405 |
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| 406 | void DST_inverse(const ColumnVector& V, ColumnVector& U)
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| 407 | {
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| 408 | // Inverse of discrete sine transform, type I
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| 409 | Tracer trace("DST_inverse");
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| 410 | REPORT
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| 411 | const int n = V.Nrows()-1; // length of transform
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| 412 | const int n2 = n / 2; const int n21 = n2 + 1;
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| 413 | if (n != 2 * n2)
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| 414 | Throw(ProgramException("Vector length not multiple of 2", V));
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| 415 | ColumnVector X(n21), Y(n21);
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| 416 | Real* x = X.Store(); Real* y = Y.Store(); Real* v = V.Store();
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| 417 | Real vi = *(++v); *x++ = 2 * vi; *y++ = 0.0;
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| 418 | int i = n2-1;
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| 419 | while (i--) { *y++ = *(++v); Real vi2 = *(++v); *x++ = vi2 - vi; vi = vi2; }
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| 420 | *x = -2 * vi; *y = 0.0;
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| 421 | ColumnVector A; RealFFTI(X, Y, A);
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| 422 | X.cleanup(); Y.cleanup(); U.resize(n+1);
|
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| 423 | Real* a = A.Store(); Real* b = a + n; Real* u = U.Store(); v = u + n;
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| 424 | i = n2; int k = 0; *u++ = 0.0; *v-- = 0.0;
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| 425 | while (i--)
|
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| 426 | {
|
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| 427 | Real s = sin(1.5707963267948966192 * (++k) / n2);
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| 428 | Real ai = *(++a); Real bi = *(--b);
|
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| 429 | Real az = (ai + bi) / 4 / s; Real bz = (ai - bi) / 2;
|
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| 430 | *u++ = az - bz; *v-- = az + bz;
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| 431 | }
|
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| 432 | }
|
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| 433 |
|
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| 434 | void DST(const ColumnVector& U, ColumnVector& V)
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| 435 | {
|
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| 436 | // Discrete sine transform, type I
|
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| 437 | Tracer trace("DST");
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| 438 | REPORT
|
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| 439 | DST_inverse(U, V);
|
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| 440 | V *= (V.Nrows()-1)/2;
|
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| 441 | }
|
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| 442 |
|
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| 443 | // Two dimensional FFT
|
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| 444 | void FFT2(const Matrix& U, const Matrix& V, Matrix& X, Matrix& Y)
|
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| 445 | {
|
---|
| 446 | Tracer trace("FFT2");
|
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| 447 | REPORT
|
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| 448 | int m = U.Nrows(); int n = U.Ncols();
|
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| 449 | if (m != V.Nrows() || n != V.Ncols() || m == 0 || n == 0)
|
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| 450 | Throw(ProgramException("Matrix dimensions unequal or zero", U, V));
|
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| 451 | X = U; Y = V;
|
---|
| 452 | int i; ColumnVector CVR; ColumnVector CVI;
|
---|
| 453 | for (i = 1; i <= m; ++i)
|
---|
| 454 | {
|
---|
| 455 | FFT(X.Row(i).t(), Y.Row(i).t(), CVR, CVI);
|
---|
| 456 | X.Row(i) = CVR.t(); Y.Row(i) = CVI.t();
|
---|
| 457 | }
|
---|
| 458 | for (i = 1; i <= n; ++i)
|
---|
| 459 | {
|
---|
| 460 | FFT(X.Column(i), Y.Column(i), CVR, CVI);
|
---|
| 461 | X.Column(i) = CVR; Y.Column(i) = CVI;
|
---|
| 462 | }
|
---|
| 463 | }
|
---|
| 464 |
|
---|
| 465 | void FFT2I(const Matrix& U, const Matrix& V, Matrix& X, Matrix& Y)
|
---|
| 466 | {
|
---|
| 467 | // Inverse transform
|
---|
| 468 | Tracer trace("FFT2I");
|
---|
| 469 | REPORT
|
---|
| 470 | FFT2(U,-V,X,Y);
|
---|
| 471 | const Real n = X.Nrows() * X.Ncols(); X /= n; Y /= (-n);
|
---|
| 472 | }
|
---|
| 473 |
|
---|
| 474 |
|
---|
| 475 | #ifdef use_namespace
|
---|
| 476 | }
|
---|
| 477 | #endif
|
---|
| 478 |
|
---|
| 479 |
|
---|
| 480 | ///@}
|
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