📄 fni_11.c

📁 FFTW, a collection of fast C routines to compute the Discrete Fourier Transform in one or more dime
💻 C
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/* * Copyright (c) 1997-1999, 2003 Massachusetts Institute of Technology * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA * *//* This file was automatically generated --- DO NOT EDIT *//* Generated on Mon Mar 24 02:06:29 EST 2003 */#include "fftw-int.h"#include "fftw.h"/* Generated by: /homee/stevenj/cvs/fftw/gensrc/genfft -magic-alignment-check -magic-twiddle-load-all -magic-variables 4 -magic-loopi -notwiddleinv 11 *//* * This function contains 140 FP additions, 100 FP multiplications, * (or, 140 additions, 100 multiplications, 0 fused multiply/add), * 30 stack variables, and 44 memory accesses */static const fftw_real K959492973 =FFTW_KONST(+0.959492973614497389890368057066327699062454848);static const fftw_real K654860733 =FFTW_KONST(+0.654860733945285064056925072466293553183791199);static const fftw_real K142314838 =FFTW_KONST(+0.142314838273285140443792668616369668791051361);static const fftw_real K415415013 =FFTW_KONST(+0.415415013001886425529274149229623203524004910);static const fftw_real K841253532 =FFTW_KONST(+0.841253532831181168861811648919367717513292498);static const fftw_real K540640817 =FFTW_KONST(+0.540640817455597582107635954318691695431770608);static const fftw_real K909631995 =FFTW_KONST(+0.909631995354518371411715383079028460060241051);static const fftw_real K281732556 =FFTW_KONST(+0.281732556841429697711417915346616899035777899);static const fftw_real K755749574 =FFTW_KONST(+0.755749574354258283774035843972344420179717445);static const fftw_real K989821441 =FFTW_KONST(+0.989821441880932732376092037776718787376519372);/* * Generator Id's :  * $Id: exprdag.ml,v 1.43 2003/03/16 23:43:46 stevenj Exp $ * $Id: fft.ml,v 1.44 2003/03/16 23:43:46 stevenj Exp $ * $Id: to_c.ml,v 1.26 2003/03/16 23:43:46 stevenj Exp $ */void fftwi_no_twiddle_11(const fftw_complex *input, fftw_complex *output,			 int istride, int ostride){     fftw_real tmp1;     fftw_real tmp23;     fftw_real tmp4;     fftw_real tmp17;     fftw_real tmp32;     fftw_real tmp51;     fftw_real tmp38;     fftw_real tmp53;     fftw_real tmp7;     fftw_real tmp21;     fftw_real tmp10;     fftw_real tmp18;     fftw_real tmp29;     fftw_real tmp50;     fftw_real tmp13;     fftw_real tmp19;     fftw_real tmp35;     fftw_real tmp49;     fftw_real tmp26;     fftw_real tmp52;     fftw_real tmp16;     fftw_real tmp20;     ASSERT_ALIGNED_DOUBLE;     {	  fftw_real tmp2;	  fftw_real tmp3;	  fftw_real tmp30;	  fftw_real tmp31;	  ASSERT_ALIGNED_DOUBLE;	  tmp1 = c_re(input[0]);	  tmp23 = c_im(input[0]);	  tmp2 = c_re(input[istride]);	  tmp3 = c_re(input[10 * istride]);	  tmp4 = tmp2 + tmp3;	  tmp17 = tmp2 - tmp3;	  tmp30 = c_im(input[istride]);	  tmp31 = c_im(input[10 * istride]);	  tmp32 = tmp30 + tmp31;	  tmp51 = tmp31 - tmp30;	  {	       fftw_real tmp36;	       fftw_real tmp37;	       fftw_real tmp5;	       fftw_real tmp6;	       ASSERT_ALIGNED_DOUBLE;	       tmp36 = c_im(input[2 * istride]);	       tmp37 = c_im(input[9 * istride]);	       tmp38 = tmp36 + tmp37;	       tmp53 = tmp37 - tmp36;	       tmp5 = c_re(input[2 * istride]);	       tmp6 = c_re(input[9 * istride]);	       tmp7 = tmp5 + tmp6;	       tmp21 = tmp5 - tmp6;	  }     }     {	  fftw_real tmp8;	  fftw_real tmp9;	  fftw_real tmp33;	  fftw_real tmp34;	  ASSERT_ALIGNED_DOUBLE;	  tmp8 = c_re(input[3 * istride]);	  tmp9 = c_re(input[8 * istride]);	  tmp10 = tmp8 + tmp9;	  tmp18 = tmp8 - tmp9;	  {	       fftw_real tmp27;	       fftw_real tmp28;	       fftw_real tmp11;	       fftw_real tmp12;	       ASSERT_ALIGNED_DOUBLE;	       tmp27 = c_im(input[3 * istride]);	       tmp28 = c_im(input[8 * istride]);	       tmp29 = tmp27 + tmp28;	       tmp50 = tmp28 - tmp27;	       tmp11 = c_re(input[4 * istride]);	       tmp12 = c_re(input[7 * istride]);	       tmp13 = tmp11 + tmp12;	       tmp19 = tmp11 - tmp12;	  }	  tmp33 = c_im(input[4 * istride]);	  tmp34 = c_im(input[7 * istride]);	  tmp35 = tmp33 + tmp34;	  tmp49 = tmp34 - tmp33;	  {	       fftw_real tmp24;	       fftw_real tmp25;	       fftw_real tmp14;	       fftw_real tmp15;	       ASSERT_ALIGNED_DOUBLE;	       tmp24 = c_im(input[5 * istride]);	       tmp25 = c_im(input[6 * istride]);	       tmp26 = tmp24 + tmp25;	       tmp52 = tmp25 - tmp24;	       tmp14 = c_re(input[5 * istride]);	       tmp15 = c_re(input[6 * istride]);	       tmp16 = tmp14 + tmp15;	       tmp20 = tmp14 - tmp15;	  }     }     {	  fftw_real tmp56;	  fftw_real tmp55;	  fftw_real tmp44;	  fftw_real tmp45;	  ASSERT_ALIGNED_DOUBLE;	  c_re(output[0]) = tmp1 + tmp4 + tmp7 + tmp10 + tmp13 + tmp16;	  {	       fftw_real tmp62;	       fftw_real tmp61;	       fftw_real tmp58;	       fftw_real tmp57;	       ASSERT_ALIGNED_DOUBLE;	       tmp62 =		   (K989821441 * tmp52) + (K755749574 * tmp50) +		   (K281732556 * tmp51) - (K909631995 * tmp49) -		   (K540640817 * tmp53);	       tmp61 =		   tmp1 + (K841253532 * tmp7) + (K415415013 * tmp13) -		   (K142314838 * tmp16) - (K654860733 * tmp10) -		   (K959492973 * tmp4);	       c_re(output[6 * ostride]) = tmp61 - tmp62;	       c_re(output[5 * ostride]) = tmp61 + tmp62;	       tmp58 =		   (K909631995 * tmp53) + (K755749574 * tmp49) +		   (K281732556 * tmp52) + (K989821441 * tmp50) +		   (K540640817 * tmp51);	       tmp57 =		   tmp1 + (K841253532 * tmp4) + (K415415013 * tmp7) -		   (K959492973 * tmp16) - (K654860733 * tmp13) -		   (K142314838 * tmp10);	       c_re(output[10 * ostride]) = tmp57 - tmp58;	       c_re(output[ostride]) = tmp57 + tmp58;	  }	  tmp56 =	      (K755749574 * tmp53) + (K909631995 * tmp51) -	      (K281732556 * tmp50) - (K540640817 * tmp52) -	      (K989821441 * tmp49);	  tmp55 =	      tmp1 + (K415415013 * tmp4) + (K841253532 * tmp16) -	      (K142314838 * tmp13) - (K959492973 * tmp10) -	      (K654860733 * tmp7);	  c_re(output[9 * ostride]) = tmp55 - tmp56;	  c_re(output[2 * ostride]) = tmp55 + tmp56;	  {	       fftw_real tmp60;	       fftw_real tmp59;	       fftw_real tmp54;	       fftw_real tmp48;	       ASSERT_ALIGNED_DOUBLE;	       tmp60 =		   (K540640817 * tmp49) + (K755749574 * tmp52) +		   (K989821441 * tmp51) - (K909631995 * tmp50) -		   (K281732556 * tmp53);	       tmp59 =		   tmp1 + (K415415013 * tmp10) + (K841253532 * tmp13) -		   (K654860733 * tmp16) - (K959492973 * tmp7) -		   (K142314838 * tmp4);	       c_re(output[8 * ostride]) = tmp59 - tmp60;	       c_re(output[3 * ostride]) = tmp59 + tmp60;	       tmp54 =		   (K281732556 * tmp49) + (K540640817 * tmp50) +		   (K755749574 * tmp51) - (K909631995 * tmp52) -		   (K989821441 * tmp53);	       tmp48 =		   tmp1 + (K841253532 * tmp10) + (K415415013 * tmp16) -		   (K959492973 * tmp13) - (K142314838 * tmp7) -		   (K654860733 * tmp4);	       c_re(output[7 * ostride]) = tmp48 - tmp54;	       c_re(output[4 * ostride]) = tmp48 + tmp54;	  }	  c_im(output[0]) = tmp23 + tmp38 + tmp35 + tmp26 + tmp29 + tmp32;	  {	       fftw_real tmp22;	       fftw_real tmp39;	       fftw_real tmp42;	       fftw_real tmp43;	       ASSERT_ALIGNED_DOUBLE;	       tmp22 =		   (K755749574 * tmp17) + (K540640817 * tmp18) +		   (K281732556 * tmp19) - (K909631995 * tmp20) -		   (K989821441 * tmp21);	       tmp39 =		   tmp23 + (K415415013 * tmp26) + (K841253532 * tmp29) -		   (K654860733 * tmp32) - (K959492973 * tmp35) -		   (K142314838 * tmp38);	       c_im(output[4 * ostride]) = tmp22 + tmp39;	       c_im(output[7 * ostride]) = tmp39 - tmp22;	       tmp42 =		   (K281732556 * tmp17) + (K755749574 * tmp18) +		   (K989821441 * tmp20) - (K909631995 * tmp19) -		   (K540640817 * tmp21);	       tmp43 =		   tmp23 + (K841253532 * tmp38) + (K415415013 * tmp35) -		   (K959492973 * tmp32) - (K654860733 * tmp29) -		   (K142314838 * tmp26);	       c_im(output[5 * ostride]) = tmp42 + tmp43;	       c_im(output[6 * ostride]) = tmp43 - tmp42;	  }	  tmp44 =	      (K540640817 * tmp17) + (K909631995 * tmp21) +	      (K989821441 * tmp18) + (K755749574 * tmp19) +	      (K281732556 * tmp20);	  tmp45 =	      tmp23 + (K415415013 * tmp38) + (K841253532 * tmp32) -	      (K142314838 * tmp29) - (K959492973 * tmp26) -	      (K654860733 * tmp35);	  c_im(output[ostride]) = tmp44 + tmp45;	  c_im(output[10 * ostride]) = tmp45 - tmp44;	  {	       fftw_real tmp40;	       fftw_real tmp41;	       fftw_real tmp46;	       fftw_real tmp47;	       ASSERT_ALIGNED_DOUBLE;	       tmp40 =		   (K989821441 * tmp17) + (K540640817 * tmp19) +		   (K755749574 * tmp20) - (K909631995 * tmp18) -		   (K281732556 * tmp21);	       tmp41 =		   tmp23 + (K841253532 * tmp35) + (K415415013 * tmp29) -		   (K142314838 * tmp32) - (K654860733 * tmp26) -		   (K959492973 * tmp38);	       c_im(output[3 * ostride]) = tmp40 + tmp41;	       c_im(output[8 * ostride]) = tmp41 - tmp40;	       tmp46 =		   (K909631995 * tmp17) + (K755749574 * tmp21) -		   (K540640817 * tmp20) - (K989821441 * tmp19) -		   (K281732556 * tmp18);	       tmp47 =		   tmp23 + (K841253532 * tmp26) + (K415415013 * tmp32) -		   (K959492973 * tmp29) - (K142314838 * tmp35) -		   (K654860733 * tmp38);	       c_im(output[2 * ostride]) = tmp46 + tmp47;	       c_im(output[9 * ostride]) = tmp47 - tmp46;	  }     }}fftw_codelet_desc fftwi_no_twiddle_11_desc = {     "fftwi_no_twiddle_11",     (void (*)()) fftwi_no_twiddle_11,     11,     FFTW_BACKWARD,     FFTW_NOTW,     254,     0,     (const int *) 0,};
💿 文件大小 1511 K
👤 上传用户 koalalee
📂 所属分类数学计算
🏷️ 相关标签

#collection #Transform #Discrete #routines
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