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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 07:41:08 EST 2012 */
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23
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24 #include "codelet-rdft.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_r2cb.native -fma -reorder-insns -schedule-for-pipeline -compact -variables 4 -pipeline-latency 4 -sign 1 -n 15 -name r2cb_15 -include r2cb.h */
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29
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30 /*
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31 * This function contains 64 FP additions, 43 FP multiplications,
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32 * (or, 21 additions, 0 multiplications, 43 fused multiply/add),
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33 * 54 stack variables, 9 constants, and 30 memory accesses
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34 */
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35 #include "r2cb.h"
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36
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37 static void r2cb_15(R *R0, R *R1, R *Cr, R *Ci, stride rs, stride csr, stride csi, INT v, INT ivs, INT ovs)
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38 {
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39 DK(KP559016994, +0.559016994374947424102293417182819058860154590);
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Chris@10
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40 DK(KP1_902113032, +1.902113032590307144232878666758764286811397268);
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Chris@10
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41 DK(KP250000000, +0.250000000000000000000000000000000000000000000);
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42 DK(KP866025403, +0.866025403784438646763723170752936183471402627);
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43 DK(KP1_118033988, +1.118033988749894848204586834365638117720309180);
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44 DK(KP618033988, +0.618033988749894848204586834365638117720309180);
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45 DK(KP500000000, +0.500000000000000000000000000000000000000000000);
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46 DK(KP1_732050807, +1.732050807568877293527446341505872366942805254);
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47 DK(KP2_000000000, +2.000000000000000000000000000000000000000000000);
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48 {
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49 INT i;
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50 for (i = v; i > 0; i = i - 1, R0 = R0 + ovs, R1 = R1 + ovs, Cr = Cr + ivs, Ci = Ci + ivs, MAKE_VOLATILE_STRIDE(60, rs), MAKE_VOLATILE_STRIDE(60, csr), MAKE_VOLATILE_STRIDE(60, csi)) {
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51 E TL, Tz, TM, TK;
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52 {
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53 E T3, Th, Tt, TD, TI, TH, TY, TC, TZ, Tu, Tm, Tv, Tr, Te, TW;
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54 E Tg, T1, T2, T12, T10, TV;
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55 Tg = Ci[WS(csi, 5)];
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56 T1 = Cr[0];
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57 T2 = Cr[WS(csr, 5)];
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58 {
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59 E T4, TA, T9, TF, T7, Tj, Tc, Tk, TG, Tq, Tf, Tl, TB;
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60 T4 = Cr[WS(csr, 3)];
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61 TA = Ci[WS(csi, 3)];
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62 T9 = Cr[WS(csr, 6)];
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63 Tf = T1 - T2;
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64 T3 = FMA(KP2_000000000, T2, T1);
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65 TF = Ci[WS(csi, 6)];
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66 {
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67 E Ta, Tb, T5, T6, To, Tp;
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68 T5 = Cr[WS(csr, 7)];
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69 T6 = Cr[WS(csr, 2)];
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70 Th = FMA(KP1_732050807, Tg, Tf);
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71 Tt = FNMS(KP1_732050807, Tg, Tf);
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72 Ta = Cr[WS(csr, 4)];
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73 TD = T5 - T6;
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74 T7 = T5 + T6;
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75 Tb = Cr[WS(csr, 1)];
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76 To = Ci[WS(csi, 4)];
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77 Tp = Ci[WS(csi, 1)];
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78 Tj = Ci[WS(csi, 7)];
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79 Tc = Ta + Tb;
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80 TI = Ta - Tb;
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81 Tk = Ci[WS(csi, 2)];
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82 TG = Tp - To;
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83 Tq = To + Tp;
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84 }
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85 Tl = Tj - Tk;
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86 TB = Tj + Tk;
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87 TH = FNMS(KP500000000, TG, TF);
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88 TY = TG + TF;
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89 TC = FMA(KP500000000, TB, TA);
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90 TZ = TA - TB;
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91 {
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92 E Ti, T8, Td, Tn;
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93 Ti = FNMS(KP2_000000000, T4, T7);
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94 T8 = T4 + T7;
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95 Td = T9 + Tc;
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96 Tn = FNMS(KP2_000000000, T9, Tc);
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97 Tu = FNMS(KP1_732050807, Tl, Ti);
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98 Tm = FMA(KP1_732050807, Tl, Ti);
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99 Tv = FNMS(KP1_732050807, Tq, Tn);
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100 Tr = FMA(KP1_732050807, Tq, Tn);
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101 Te = T8 + Td;
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102 TW = T8 - Td;
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103 }
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104 }
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105 T12 = FMA(KP618033988, TY, TZ);
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106 T10 = FNMS(KP618033988, TZ, TY);
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107 TV = FNMS(KP500000000, Te, T3);
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108 R0[0] = FMA(KP2_000000000, Te, T3);
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109 {
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110 E TJ, TE, TT, TP, TU, TS, Ty, Tw, Tx;
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111 {
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112 E TO, Ts, TQ, TN, TR, T11, TX;
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113 TO = Tr - Tm;
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114 Ts = Tm + Tr;
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115 T11 = FMA(KP1_118033988, TW, TV);
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116 TX = FNMS(KP1_118033988, TW, TV);
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117 TQ = FNMS(KP866025403, TI, TH);
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118 TJ = FMA(KP866025403, TI, TH);
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119 TN = FMA(KP250000000, Ts, Th);
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120 R0[WS(rs, 3)] = FNMS(KP1_902113032, T12, T11);
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121 R1[WS(rs, 4)] = FMA(KP1_902113032, T12, T11);
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122 R0[WS(rs, 6)] = FMA(KP1_902113032, T10, TX);
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123 R1[WS(rs, 1)] = FNMS(KP1_902113032, T10, TX);
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124 TR = FNMS(KP866025403, TD, TC);
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125 TE = FMA(KP866025403, TD, TC);
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126 R1[WS(rs, 2)] = Th - Ts;
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127 TT = FMA(KP559016994, TO, TN);
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128 TP = FNMS(KP559016994, TO, TN);
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129 TU = FMA(KP618033988, TQ, TR);
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130 TS = FNMS(KP618033988, TR, TQ);
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131 }
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132 Ty = Tv - Tu;
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133 Tw = Tu + Tv;
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134 R0[WS(rs, 7)] = FMA(KP1_902113032, TU, TT);
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135 R1[WS(rs, 5)] = FNMS(KP1_902113032, TU, TT);
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136 R0[WS(rs, 1)] = FMA(KP1_902113032, TS, TP);
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137 R0[WS(rs, 4)] = FNMS(KP1_902113032, TS, TP);
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138 Tx = FMA(KP250000000, Tw, Tt);
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139 R0[WS(rs, 5)] = Tt - Tw;
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140 TL = FNMS(KP559016994, Ty, Tx);
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141 Tz = FMA(KP559016994, Ty, Tx);
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142 TM = FNMS(KP618033988, TE, TJ);
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143 TK = FMA(KP618033988, TJ, TE);
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144 }
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145 }
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146 R1[WS(rs, 3)] = FMA(KP1_902113032, TM, TL);
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147 R1[WS(rs, 6)] = FNMS(KP1_902113032, TM, TL);
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148 R0[WS(rs, 2)] = FMA(KP1_902113032, TK, Tz);
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149 R1[0] = FNMS(KP1_902113032, TK, Tz);
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150 }
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151 }
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152 }
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153
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154 static const kr2c_desc desc = { 15, "r2cb_15", {21, 0, 43, 0}, &GENUS };
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155
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156 void X(codelet_r2cb_15) (planner *p) {
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157 X(kr2c_register) (p, r2cb_15, &desc);
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158 }
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159
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160 #else /* HAVE_FMA */
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161
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162 /* Generated by: ../../../genfft/gen_r2cb.native -compact -variables 4 -pipeline-latency 4 -sign 1 -n 15 -name r2cb_15 -include r2cb.h */
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163
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164 /*
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165 * This function contains 64 FP additions, 31 FP multiplications,
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166 * (or, 47 additions, 14 multiplications, 17 fused multiply/add),
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167 * 44 stack variables, 7 constants, and 30 memory accesses
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168 */
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169 #include "r2cb.h"
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170
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171 static void r2cb_15(R *R0, R *R1, R *Cr, R *Ci, stride rs, stride csr, stride csi, INT v, INT ivs, INT ovs)
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172 {
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173 DK(KP1_118033988, +1.118033988749894848204586834365638117720309180);
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174 DK(KP1_902113032, +1.902113032590307144232878666758764286811397268);
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175 DK(KP1_175570504, +1.175570504584946258337411909278145537195304875);
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176 DK(KP500000000, +0.500000000000000000000000000000000000000000000);
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177 DK(KP866025403, +0.866025403784438646763723170752936183471402627);
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178 DK(KP2_000000000, +2.000000000000000000000000000000000000000000000);
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179 DK(KP1_732050807, +1.732050807568877293527446341505872366942805254);
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180 {
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181 INT i;
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182 for (i = v; i > 0; i = i - 1, R0 = R0 + ovs, R1 = R1 + ovs, Cr = Cr + ivs, Ci = Ci + ivs, MAKE_VOLATILE_STRIDE(60, rs), MAKE_VOLATILE_STRIDE(60, csr), MAKE_VOLATILE_STRIDE(60, csi)) {
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183 E T3, Tu, Ti, TB, TZ, T10, TE, TG, TJ, Tn, Tv, Ts, Tw, T8, Td;
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184 E Te;
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185 {
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186 E Th, T1, T2, Tf, Tg;
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187 Tg = Ci[WS(csi, 5)];
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188 Th = KP1_732050807 * Tg;
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189 T1 = Cr[0];
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190 T2 = Cr[WS(csr, 5)];
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191 Tf = T1 - T2;
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192 T3 = FMA(KP2_000000000, T2, T1);
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193 Tu = Tf - Th;
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194 Ti = Tf + Th;
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195 }
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196 {
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197 E T4, TD, T9, TI, T5, T6, T7, Ta, Tb, Tc, Tr, TH, Tm, TC, Tj;
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198 E To;
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199 T4 = Cr[WS(csr, 3)];
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200 TD = Ci[WS(csi, 3)];
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201 T9 = Cr[WS(csr, 6)];
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202 TI = Ci[WS(csi, 6)];
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203 T5 = Cr[WS(csr, 7)];
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204 T6 = Cr[WS(csr, 2)];
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205 T7 = T5 + T6;
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206 Ta = Cr[WS(csr, 4)];
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207 Tb = Cr[WS(csr, 1)];
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208 Tc = Ta + Tb;
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209 {
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210 E Tp, Tq, Tk, Tl;
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211 Tp = Ci[WS(csi, 4)];
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212 Tq = Ci[WS(csi, 1)];
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213 Tr = KP866025403 * (Tp + Tq);
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214 TH = Tp - Tq;
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215 Tk = Ci[WS(csi, 7)];
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216 Tl = Ci[WS(csi, 2)];
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217 Tm = KP866025403 * (Tk - Tl);
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218 TC = Tk + Tl;
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219 }
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220 TB = KP866025403 * (T5 - T6);
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221 TZ = TD - TC;
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222 T10 = TI - TH;
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223 TE = FMA(KP500000000, TC, TD);
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224 TG = KP866025403 * (Ta - Tb);
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225 TJ = FMA(KP500000000, TH, TI);
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226 Tj = FNMS(KP500000000, T7, T4);
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227 Tn = Tj - Tm;
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228 Tv = Tj + Tm;
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229 To = FNMS(KP500000000, Tc, T9);
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230 Ts = To - Tr;
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231 Tw = To + Tr;
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232 T8 = T4 + T7;
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233 Td = T9 + Tc;
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234 Te = T8 + Td;
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235 }
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236 R0[0] = FMA(KP2_000000000, Te, T3);
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237 {
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238 E T11, T13, TY, T12, TW, TX;
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239 T11 = FNMS(KP1_902113032, T10, KP1_175570504 * TZ);
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240 T13 = FMA(KP1_902113032, TZ, KP1_175570504 * T10);
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241 TW = FNMS(KP500000000, Te, T3);
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242 TX = KP1_118033988 * (T8 - Td);
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243 TY = TW - TX;
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244 T12 = TX + TW;
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245 R0[WS(rs, 6)] = TY - T11;
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246 R1[WS(rs, 4)] = T12 + T13;
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247 R1[WS(rs, 1)] = TY + T11;
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248 R0[WS(rs, 3)] = T12 - T13;
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249 }
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250 {
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251 E TP, Tt, TO, TT, TV, TR, TS, TU, TQ;
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252 TP = KP1_118033988 * (Tn - Ts);
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253 Tt = Tn + Ts;
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254 TO = FNMS(KP500000000, Tt, Ti);
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255 TR = TE - TB;
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256 TS = TJ - TG;
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257 TT = FNMS(KP1_902113032, TS, KP1_175570504 * TR);
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258 TV = FMA(KP1_902113032, TR, KP1_175570504 * TS);
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259 R1[WS(rs, 2)] = FMA(KP2_000000000, Tt, Ti);
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260 TU = TP + TO;
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261 R1[WS(rs, 5)] = TU - TV;
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262 R0[WS(rs, 7)] = TU + TV;
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263 TQ = TO - TP;
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264 R0[WS(rs, 1)] = TQ - TT;
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265 R0[WS(rs, 4)] = TQ + TT;
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266 }
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267 {
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268 E Tz, Tx, Ty, TL, TN, TF, TK, TM, TA;
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269 Tz = KP1_118033988 * (Tv - Tw);
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Chris@10
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270 Tx = Tv + Tw;
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Chris@10
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271 Ty = FNMS(KP500000000, Tx, Tu);
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Chris@10
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272 TF = TB + TE;
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Chris@10
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273 TK = TG + TJ;
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Chris@10
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274 TL = FNMS(KP1_902113032, TK, KP1_175570504 * TF);
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275 TN = FMA(KP1_902113032, TF, KP1_175570504 * TK);
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Chris@10
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276 R0[WS(rs, 5)] = FMA(KP2_000000000, Tx, Tu);
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277 TM = Tz + Ty;
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Chris@10
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278 R1[0] = TM - TN;
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Chris@10
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279 R0[WS(rs, 2)] = TM + TN;
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Chris@10
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280 TA = Ty - Tz;
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Chris@10
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281 R1[WS(rs, 3)] = TA - TL;
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Chris@10
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282 R1[WS(rs, 6)] = TA + TL;
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Chris@10
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283 }
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Chris@10
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284 }
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Chris@10
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285 }
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Chris@10
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286 }
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287
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288 static const kr2c_desc desc = { 15, "r2cb_15", {47, 14, 17, 0}, &GENUS };
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289
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290 void X(codelet_r2cb_15) (planner *p) {
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Chris@10
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291 X(kr2c_register) (p, r2cb_15, &desc);
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Chris@10
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292 }
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293
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294 #endif /* HAVE_FMA */
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