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Chris@10
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1 /*
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Chris@10
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2 * Copyright (c) 2003, 2007-11 Matteo Frigo
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3 * Copyright (c) 2003, 2007-11 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 /* This file was automatically generated --- DO NOT EDIT */
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22 /* Generated on Sun Nov 25 07:39:04 EST 2012 */
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23
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24 #include "codelet-dft.h"
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25
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26 #ifdef HAVE_FMA
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27
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28 /* Generated by: ../../../genfft/gen_twiddle_c.native -fma -reorder-insns -schedule-for-pipeline -simd -compact -variables 4 -pipeline-latency 8 -n 12 -name t1bv_12 -include t1b.h -sign 1 */
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29
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30 /*
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31 * This function contains 59 FP additions, 42 FP multiplications,
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32 * (or, 41 additions, 24 multiplications, 18 fused multiply/add),
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33 * 41 stack variables, 2 constants, and 24 memory accesses
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34 */
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35 #include "t1b.h"
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36
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37 static void t1bv_12(R *ri, R *ii, const R *W, stride rs, INT mb, INT me, INT ms)
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38 {
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39 DVK(KP866025403, +0.866025403784438646763723170752936183471402627);
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40 DVK(KP500000000, +0.500000000000000000000000000000000000000000000);
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41 {
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42 INT m;
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43 R *x;
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44 x = ii;
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45 for (m = mb, W = W + (mb * ((TWVL / VL) * 22)); m < me; m = m + VL, x = x + (VL * ms), W = W + (TWVL * 22), MAKE_VOLATILE_STRIDE(12, rs)) {
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46 V TI, Ti, TA, T7, Tm, TE, Tw, Tk, Tf, TB, TU, TM;
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47 {
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48 V T9, TK, Tj, TL, Te;
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49 {
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50 V T1, T4, T2, Tp, Tt, Tr;
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51 T1 = LD(&(x[0]), ms, &(x[0]));
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52 T4 = LD(&(x[WS(rs, 8)]), ms, &(x[0]));
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53 T2 = LD(&(x[WS(rs, 4)]), ms, &(x[0]));
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54 Tp = LD(&(x[WS(rs, 9)]), ms, &(x[WS(rs, 1)]));
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55 Tt = LD(&(x[WS(rs, 5)]), ms, &(x[WS(rs, 1)]));
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56 Tr = LD(&(x[WS(rs, 1)]), ms, &(x[WS(rs, 1)]));
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57 {
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58 V T5, T3, Tq, Tu, Ts, Td, Tb, T8, Tc, Ta;
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59 T8 = LD(&(x[WS(rs, 6)]), ms, &(x[0]));
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60 Tc = LD(&(x[WS(rs, 2)]), ms, &(x[0]));
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61 Ta = LD(&(x[WS(rs, 10)]), ms, &(x[0]));
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62 T5 = BYTW(&(W[TWVL * 14]), T4);
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63 T3 = BYTW(&(W[TWVL * 6]), T2);
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64 Tq = BYTW(&(W[TWVL * 16]), Tp);
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65 Tu = BYTW(&(W[TWVL * 8]), Tt);
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66 Ts = BYTW(&(W[0]), Tr);
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67 T9 = BYTW(&(W[TWVL * 10]), T8);
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68 Td = BYTW(&(W[TWVL * 2]), Tc);
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69 Tb = BYTW(&(W[TWVL * 18]), Ta);
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70 {
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71 V Th, T6, Tl, Tv;
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72 Th = LD(&(x[WS(rs, 3)]), ms, &(x[WS(rs, 1)]));
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73 TK = VSUB(T3, T5);
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74 T6 = VADD(T3, T5);
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75 Tl = LD(&(x[WS(rs, 11)]), ms, &(x[WS(rs, 1)]));
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76 Tv = VADD(Ts, Tu);
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77 TI = VSUB(Tu, Ts);
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78 Tj = LD(&(x[WS(rs, 7)]), ms, &(x[WS(rs, 1)]));
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79 TL = VSUB(Tb, Td);
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80 Te = VADD(Tb, Td);
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81 Ti = BYTW(&(W[TWVL * 4]), Th);
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82 TA = VFNMS(LDK(KP500000000), T6, T1);
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83 T7 = VADD(T1, T6);
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84 Tm = BYTW(&(W[TWVL * 20]), Tl);
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85 TE = VFNMS(LDK(KP500000000), Tv, Tq);
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86 Tw = VADD(Tq, Tv);
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87 }
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88 }
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89 }
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90 Tk = BYTW(&(W[TWVL * 12]), Tj);
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91 Tf = VADD(T9, Te);
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92 TB = VFNMS(LDK(KP500000000), Te, T9);
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93 TU = VSUB(TK, TL);
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94 TM = VADD(TK, TL);
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95 }
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96 {
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97 V Tn, TH, TC, TQ, Ty, Tg;
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98 Tn = VADD(Tk, Tm);
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99 TH = VSUB(Tk, Tm);
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100 TC = VADD(TA, TB);
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101 TQ = VSUB(TA, TB);
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102 Ty = VADD(T7, Tf);
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103 Tg = VSUB(T7, Tf);
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104 {
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105 V To, TD, TJ, TR;
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106 To = VADD(Ti, Tn);
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107 TD = VFNMS(LDK(KP500000000), Tn, Ti);
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108 TJ = VSUB(TH, TI);
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109 TR = VADD(TH, TI);
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110 {
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111 V TP, TN, TW, TS, TO, TG, TX, TV;
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112 {
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113 V Tz, Tx, TF, TT;
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114 Tz = VADD(To, Tw);
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115 Tx = VSUB(To, Tw);
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116 TF = VADD(TD, TE);
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117 TT = VSUB(TD, TE);
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118 TP = VMUL(LDK(KP866025403), VADD(TM, TJ));
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119 TN = VMUL(LDK(KP866025403), VSUB(TJ, TM));
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120 TW = VFMA(LDK(KP866025403), TR, TQ);
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121 TS = VFNMS(LDK(KP866025403), TR, TQ);
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122 ST(&(x[WS(rs, 6)]), VSUB(Ty, Tz), ms, &(x[0]));
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123 ST(&(x[0]), VADD(Ty, Tz), ms, &(x[0]));
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124 ST(&(x[WS(rs, 9)]), VFMAI(Tx, Tg), ms, &(x[WS(rs, 1)]));
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125 ST(&(x[WS(rs, 3)]), VFNMSI(Tx, Tg), ms, &(x[WS(rs, 1)]));
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126 TO = VADD(TC, TF);
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127 TG = VSUB(TC, TF);
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128 TX = VFNMS(LDK(KP866025403), TU, TT);
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129 TV = VFMA(LDK(KP866025403), TU, TT);
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130 }
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131 ST(&(x[WS(rs, 8)]), VFNMSI(TP, TO), ms, &(x[0]));
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132 ST(&(x[WS(rs, 4)]), VFMAI(TP, TO), ms, &(x[0]));
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133 ST(&(x[WS(rs, 2)]), VFMAI(TN, TG), ms, &(x[0]));
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134 ST(&(x[WS(rs, 10)]), VFNMSI(TN, TG), ms, &(x[0]));
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135 ST(&(x[WS(rs, 5)]), VFMAI(TX, TW), ms, &(x[WS(rs, 1)]));
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136 ST(&(x[WS(rs, 7)]), VFNMSI(TX, TW), ms, &(x[WS(rs, 1)]));
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137 ST(&(x[WS(rs, 11)]), VFNMSI(TV, TS), ms, &(x[WS(rs, 1)]));
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138 ST(&(x[WS(rs, 1)]), VFMAI(TV, TS), ms, &(x[WS(rs, 1)]));
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139 }
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140 }
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141 }
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142 }
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143 }
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144 VLEAVE();
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145 }
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146
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147 static const tw_instr twinstr[] = {
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148 VTW(0, 1),
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149 VTW(0, 2),
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150 VTW(0, 3),
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151 VTW(0, 4),
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152 VTW(0, 5),
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153 VTW(0, 6),
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154 VTW(0, 7),
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155 VTW(0, 8),
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156 VTW(0, 9),
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157 VTW(0, 10),
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158 VTW(0, 11),
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159 {TW_NEXT, VL, 0}
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160 };
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161
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162 static const ct_desc desc = { 12, XSIMD_STRING("t1bv_12"), twinstr, &GENUS, {41, 24, 18, 0}, 0, 0, 0 };
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163
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164 void XSIMD(codelet_t1bv_12) (planner *p) {
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165 X(kdft_dit_register) (p, t1bv_12, &desc);
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166 }
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167 #else /* HAVE_FMA */
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168
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169 /* Generated by: ../../../genfft/gen_twiddle_c.native -simd -compact -variables 4 -pipeline-latency 8 -n 12 -name t1bv_12 -include t1b.h -sign 1 */
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170
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171 /*
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172 * This function contains 59 FP additions, 30 FP multiplications,
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173 * (or, 55 additions, 26 multiplications, 4 fused multiply/add),
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174 * 28 stack variables, 2 constants, and 24 memory accesses
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175 */
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176 #include "t1b.h"
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177
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178 static void t1bv_12(R *ri, R *ii, const R *W, stride rs, INT mb, INT me, INT ms)
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179 {
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180 DVK(KP866025403, +0.866025403784438646763723170752936183471402627);
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181 DVK(KP500000000, +0.500000000000000000000000000000000000000000000);
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182 {
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183 INT m;
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184 R *x;
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185 x = ii;
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186 for (m = mb, W = W + (mb * ((TWVL / VL) * 22)); m < me; m = m + VL, x = x + (VL * ms), W = W + (TWVL * 22), MAKE_VOLATILE_STRIDE(12, rs)) {
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187 V T1, Tt, T6, T7, TB, Tq, TC, TD, T9, Tu, Te, Tf, Tx, Tl, Ty;
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188 V Tz;
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189 {
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190 V T5, T3, T4, T2;
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191 T1 = LD(&(x[0]), ms, &(x[0]));
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192 T4 = LD(&(x[WS(rs, 8)]), ms, &(x[0]));
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193 T5 = BYTW(&(W[TWVL * 14]), T4);
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194 T2 = LD(&(x[WS(rs, 4)]), ms, &(x[0]));
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195 T3 = BYTW(&(W[TWVL * 6]), T2);
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196 Tt = VSUB(T3, T5);
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197 T6 = VADD(T3, T5);
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198 T7 = VFNMS(LDK(KP500000000), T6, T1);
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199 }
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200 {
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201 V Tn, Tp, Tm, TA, To;
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202 Tm = LD(&(x[WS(rs, 1)]), ms, &(x[WS(rs, 1)]));
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203 Tn = BYTW(&(W[0]), Tm);
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204 TA = LD(&(x[WS(rs, 9)]), ms, &(x[WS(rs, 1)]));
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205 TB = BYTW(&(W[TWVL * 16]), TA);
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206 To = LD(&(x[WS(rs, 5)]), ms, &(x[WS(rs, 1)]));
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207 Tp = BYTW(&(W[TWVL * 8]), To);
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208 Tq = VSUB(Tn, Tp);
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209 TC = VADD(Tn, Tp);
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210 TD = VFNMS(LDK(KP500000000), TC, TB);
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211 }
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212 {
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213 V Td, Tb, T8, Tc, Ta;
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214 T8 = LD(&(x[WS(rs, 6)]), ms, &(x[0]));
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215 T9 = BYTW(&(W[TWVL * 10]), T8);
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216 Tc = LD(&(x[WS(rs, 2)]), ms, &(x[0]));
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217 Td = BYTW(&(W[TWVL * 2]), Tc);
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218 Ta = LD(&(x[WS(rs, 10)]), ms, &(x[0]));
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219 Tb = BYTW(&(W[TWVL * 18]), Ta);
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220 Tu = VSUB(Tb, Td);
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221 Te = VADD(Tb, Td);
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222 Tf = VFNMS(LDK(KP500000000), Te, T9);
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223 }
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224 {
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225 V Ti, Tk, Th, Tw, Tj;
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226 Th = LD(&(x[WS(rs, 7)]), ms, &(x[WS(rs, 1)]));
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227 Ti = BYTW(&(W[TWVL * 12]), Th);
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228 Tw = LD(&(x[WS(rs, 3)]), ms, &(x[WS(rs, 1)]));
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229 Tx = BYTW(&(W[TWVL * 4]), Tw);
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230 Tj = LD(&(x[WS(rs, 11)]), ms, &(x[WS(rs, 1)]));
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231 Tk = BYTW(&(W[TWVL * 20]), Tj);
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232 Tl = VSUB(Ti, Tk);
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233 Ty = VADD(Ti, Tk);
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234 Tz = VFNMS(LDK(KP500000000), Ty, Tx);
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235 }
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236 {
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237 V Ts, TG, TF, TH;
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238 {
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239 V Tg, Tr, Tv, TE;
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240 Tg = VSUB(T7, Tf);
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241 Tr = VMUL(LDK(KP866025403), VSUB(Tl, Tq));
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242 Ts = VSUB(Tg, Tr);
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243 TG = VADD(Tg, Tr);
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244 Tv = VMUL(LDK(KP866025403), VSUB(Tt, Tu));
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245 TE = VSUB(Tz, TD);
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246 TF = VBYI(VADD(Tv, TE));
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247 TH = VBYI(VSUB(TE, Tv));
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248 }
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249 ST(&(x[WS(rs, 11)]), VSUB(Ts, TF), ms, &(x[WS(rs, 1)]));
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250 ST(&(x[WS(rs, 5)]), VADD(TG, TH), ms, &(x[WS(rs, 1)]));
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251 ST(&(x[WS(rs, 1)]), VADD(Ts, TF), ms, &(x[WS(rs, 1)]));
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252 ST(&(x[WS(rs, 7)]), VSUB(TG, TH), ms, &(x[WS(rs, 1)]));
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253 }
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254 {
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255 V TS, TW, TV, TX;
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256 {
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257 V TQ, TR, TT, TU;
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258 TQ = VADD(T1, T6);
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259 TR = VADD(T9, Te);
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260 TS = VSUB(TQ, TR);
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261 TW = VADD(TQ, TR);
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262 TT = VADD(Tx, Ty);
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263 TU = VADD(TB, TC);
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264 TV = VBYI(VSUB(TT, TU));
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265 TX = VADD(TT, TU);
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266 }
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267 ST(&(x[WS(rs, 3)]), VSUB(TS, TV), ms, &(x[WS(rs, 1)]));
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268 ST(&(x[0]), VADD(TW, TX), ms, &(x[0]));
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269 ST(&(x[WS(rs, 9)]), VADD(TS, TV), ms, &(x[WS(rs, 1)]));
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Chris@10
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270 ST(&(x[WS(rs, 6)]), VSUB(TW, TX), ms, &(x[0]));
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Chris@10
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271 }
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Chris@10
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272 {
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273 V TK, TO, TN, TP;
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274 {
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275 V TI, TJ, TL, TM;
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276 TI = VADD(Tl, Tq);
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277 TJ = VADD(Tt, Tu);
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278 TK = VBYI(VMUL(LDK(KP866025403), VSUB(TI, TJ)));
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279 TO = VBYI(VMUL(LDK(KP866025403), VADD(TJ, TI)));
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280 TL = VADD(T7, Tf);
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281 TM = VADD(Tz, TD);
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282 TN = VSUB(TL, TM);
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283 TP = VADD(TL, TM);
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284 }
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285 ST(&(x[WS(rs, 2)]), VADD(TK, TN), ms, &(x[0]));
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Chris@10
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286 ST(&(x[WS(rs, 8)]), VSUB(TP, TO), ms, &(x[0]));
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Chris@10
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287 ST(&(x[WS(rs, 10)]), VSUB(TN, TK), ms, &(x[0]));
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288 ST(&(x[WS(rs, 4)]), VADD(TO, TP), ms, &(x[0]));
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289 }
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290 }
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Chris@10
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291 }
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Chris@10
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292 VLEAVE();
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293 }
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294
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295 static const tw_instr twinstr[] = {
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296 VTW(0, 1),
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297 VTW(0, 2),
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298 VTW(0, 3),
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299 VTW(0, 4),
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300 VTW(0, 5),
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301 VTW(0, 6),
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302 VTW(0, 7),
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303 VTW(0, 8),
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304 VTW(0, 9),
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305 VTW(0, 10),
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306 VTW(0, 11),
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307 {TW_NEXT, VL, 0}
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308 };
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309
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Chris@10
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310 static const ct_desc desc = { 12, XSIMD_STRING("t1bv_12"), twinstr, &GENUS, {55, 26, 4, 0}, 0, 0, 0 };
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Chris@10
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311
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Chris@10
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312 void XSIMD(codelet_t1bv_12) (planner *p) {
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Chris@10
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313 X(kdft_dit_register) (p, t1bv_12, &desc);
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Chris@10
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314 }
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Chris@10
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315 #endif /* HAVE_FMA */
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