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cannam@167
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1 /*
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cannam@167
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2 * Copyright (c) 2003, 2007-14 Matteo Frigo
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3 * Copyright (c) 2003, 2007-14 Massachusetts Institute of Technology
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4 *
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5 * This program is free software; you can redistribute it and/or modify
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6 * it under the terms of the GNU General Public License as published by
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7 * the Free Software Foundation; either version 2 of the License, or
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8 * (at your option) any later version.
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9 *
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10 * This program is distributed in the hope that it will be useful,
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11 * but WITHOUT ANY WARRANTY; without even the implied warranty of
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12 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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13 * GNU General Public License for more details.
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14 *
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15 * You should have received a copy of the GNU General Public License
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16 * along with this program; if not, write to the Free Software
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17 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
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18 *
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19 */
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20
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21
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22 /* trigonometric functions */
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23 #include "kernel/ifftw.h"
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24 #include <math.h>
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25
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26 #if defined(TRIGREAL_IS_LONG_DOUBLE)
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27 # define COS cosl
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28 # define SIN sinl
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29 # define KTRIG(x) (x##L)
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30 # if defined(HAVE_DECL_SINL) && !HAVE_DECL_SINL
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31 extern long double sinl(long double x);
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32 # endif
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33 # if defined(HAVE_DECL_COSL) && !HAVE_DECL_COSL
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34 extern long double cosl(long double x);
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35 # endif
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36 #elif defined(TRIGREAL_IS_QUAD)
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37 # define COS cosq
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38 # define SIN sinq
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39 # define KTRIG(x) (x##Q)
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40 extern __float128 sinq(__float128 x);
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41 extern __float128 cosq(__float128 x);
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42 #else
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43 # define COS cos
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44 # define SIN sin
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45 # define KTRIG(x) (x)
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46 #endif
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47
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48 static const trigreal K2PI =
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49 KTRIG(6.2831853071795864769252867665590057683943388);
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50 #define by2pi(m, n) ((K2PI * (m)) / (n))
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51
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52 /*
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53 * Improve accuracy by reducing x to range [0..1/8]
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54 * before multiplication by 2 * PI.
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55 */
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56
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57 static void real_cexp(INT m, INT n, trigreal *out)
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58 {
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59 trigreal theta, c, s, t;
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60 unsigned octant = 0;
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61 INT quarter_n = n;
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62
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63 n += n; n += n;
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64 m += m; m += m;
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65
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66 if (m < 0) m += n;
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67 if (m > n - m) { m = n - m; octant |= 4; }
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68 if (m - quarter_n > 0) { m = m - quarter_n; octant |= 2; }
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69 if (m > quarter_n - m) { m = quarter_n - m; octant |= 1; }
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70
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71 theta = by2pi(m, n);
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72 c = COS(theta); s = SIN(theta);
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73
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74 if (octant & 1) { t = c; c = s; s = t; }
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75 if (octant & 2) { t = c; c = -s; s = t; }
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76 if (octant & 4) { s = -s; }
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77
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78 out[0] = c;
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79 out[1] = s;
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80 }
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81
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82 static INT choose_twshft(INT n)
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83 {
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84 INT log2r = 0;
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85 while (n > 0) {
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86 ++log2r;
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87 n /= 4;
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88 }
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89 return log2r;
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90 }
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91
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92 static void cexpl_sqrtn_table(triggen *p, INT m, trigreal *res)
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93 {
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94 m += p->n * (m < 0);
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95
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96 {
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97 INT m0 = m & p->twmsk;
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98 INT m1 = m >> p->twshft;
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99 trigreal wr0 = p->W0[2 * m0];
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100 trigreal wi0 = p->W0[2 * m0 + 1];
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101 trigreal wr1 = p->W1[2 * m1];
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102 trigreal wi1 = p->W1[2 * m1 + 1];
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103
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104 res[0] = wr1 * wr0 - wi1 * wi0;
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105 res[1] = wi1 * wr0 + wr1 * wi0;
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106 }
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107 }
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108
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109 /* multiply (xr, xi) by exp(FFT_SIGN * 2*pi*i*m/n) */
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110 static void rotate_sqrtn_table(triggen *p, INT m, R xr, R xi, R *res)
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111 {
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112 m += p->n * (m < 0);
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113
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114 {
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115 INT m0 = m & p->twmsk;
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116 INT m1 = m >> p->twshft;
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117 trigreal wr0 = p->W0[2 * m0];
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118 trigreal wi0 = p->W0[2 * m0 + 1];
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119 trigreal wr1 = p->W1[2 * m1];
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120 trigreal wi1 = p->W1[2 * m1 + 1];
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121 trigreal wr = wr1 * wr0 - wi1 * wi0;
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122 trigreal wi = wi1 * wr0 + wr1 * wi0;
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123
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124 #if FFT_SIGN == -1
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125 res[0] = xr * wr + xi * wi;
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126 res[1] = xi * wr - xr * wi;
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127 #else
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128 res[0] = xr * wr - xi * wi;
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129 res[1] = xi * wr + xr * wi;
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130 #endif
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131 }
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132 }
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133
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134 static void cexpl_sincos(triggen *p, INT m, trigreal *res)
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135 {
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136 real_cexp(m, p->n, res);
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137 }
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138
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139 static void cexp_zero(triggen *p, INT m, R *res)
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140 {
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141 UNUSED(p); UNUSED(m);
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142 res[0] = 0;
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143 res[1] = 0;
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144 }
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145
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146 static void cexpl_zero(triggen *p, INT m, trigreal *res)
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147 {
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148 UNUSED(p); UNUSED(m);
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149 res[0] = 0;
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150 res[1] = 0;
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151 }
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152
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153 static void cexp_generic(triggen *p, INT m, R *res)
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154 {
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155 trigreal resl[2];
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156 p->cexpl(p, m, resl);
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157 res[0] = (R)resl[0];
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158 res[1] = (R)resl[1];
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159 }
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160
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161 static void rotate_generic(triggen *p, INT m, R xr, R xi, R *res)
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162 {
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163 trigreal w[2];
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164 p->cexpl(p, m, w);
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165 res[0] = xr * w[0] - xi * (FFT_SIGN * w[1]);
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166 res[1] = xi * w[0] + xr * (FFT_SIGN * w[1]);
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167 }
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168
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169 triggen *X(mktriggen)(enum wakefulness wakefulness, INT n)
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170 {
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171 INT i, n0, n1;
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172 triggen *p = (triggen *)MALLOC(sizeof(*p), TWIDDLES);
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173
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174 p->n = n;
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175 p->W0 = p->W1 = 0;
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176 p->cexp = 0;
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177 p->rotate = 0;
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178
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179 switch (wakefulness) {
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180 case SLEEPY:
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181 A(0 /* can't happen */);
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182 break;
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183
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184 case AWAKE_SQRTN_TABLE: {
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185 INT twshft = choose_twshft(n);
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186
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187 p->twshft = twshft;
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188 p->twradix = ((INT)1) << twshft;
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189 p->twmsk = p->twradix - 1;
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190
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191 n0 = p->twradix;
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192 n1 = (n + n0 - 1) / n0;
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193
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194 p->W0 = (trigreal *)MALLOC(n0 * 2 * sizeof(trigreal), TWIDDLES);
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195 p->W1 = (trigreal *)MALLOC(n1 * 2 * sizeof(trigreal), TWIDDLES);
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196
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197 for (i = 0; i < n0; ++i)
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198 real_cexp(i, n, p->W0 + 2 * i);
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199
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200 for (i = 0; i < n1; ++i)
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201 real_cexp(i * p->twradix, n, p->W1 + 2 * i);
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202
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203 p->cexpl = cexpl_sqrtn_table;
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204 p->rotate = rotate_sqrtn_table;
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205 break;
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206 }
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207
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208 case AWAKE_SINCOS:
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209 p->cexpl = cexpl_sincos;
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210 break;
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211
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212 case AWAKE_ZERO:
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213 p->cexp = cexp_zero;
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214 p->cexpl = cexpl_zero;
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215 break;
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216 }
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217
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218 if (!p->cexp) {
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219 if (sizeof(trigreal) == sizeof(R))
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220 p->cexp = (void (*)(triggen *, INT, R *))p->cexpl;
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221 else
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222 p->cexp = cexp_generic;
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223 }
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224 if (!p->rotate)
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225 p->rotate = rotate_generic;
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226 return p;
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227 }
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228
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229 void X(triggen_destroy)(triggen *p)
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230 {
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231 X(ifree0)(p->W0);
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232 X(ifree0)(p->W1);
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233 X(ifree)(p);
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234 }
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