1060 lines
35 KiB
Text
1060 lines
35 KiB
Text
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//$ newfft.cpp
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// This is originally by Sande and Gentleman in 1967! I have translated from
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// Fortran into C and a little bit of C++.
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// It takes about twice as long as fftw
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// (http://theory.lcs.mit.edu/~fftw/homepage.html)
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// but is much shorter than fftw and so despite its age
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// might represent a reasonable
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// compromise between speed and complexity.
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// If you really need the speed get fftw.
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// THIS SUBROUTINE WAS WRITTEN BY G.SANDE OF PRINCETON UNIVERSITY AND
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// W.M.GENTLMAN OF THE BELL TELEPHONE LAB. IT WAS BROUGHT TO LONDON
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// BY DR. M.D. GODFREY AT THE IMPERIAL COLLEGE AND WAS ADAPTED FOR
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// BURROUGHS 6700 BY D. R. BRILLINGER AND J. PEMBERTON
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// IT REPRESENTS THE STATE OF THE ART OF COMPUTING COMPLETE FINITE
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// DISCRETE FOURIER TRANSFORMS AS OF NOV.1967.
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// OTHER PROGRAMS REQUIRED.
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// ONLY THOSE SUBROUTINES INCLUDED HERE.
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// USAGE.
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// CALL AR1DFT(N,X,Y)
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// WHERE N IS THE NUMBER OF POINTS IN THE SEQUENCE .
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// X - IS A ONE-DIMENSIONAL ARRAY CONTAINING THE REAL
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// PART OF THE SEQUENCE.
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// Y - IS A ONE-DIMENSIONAL ARRAY CONTAINING THE
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// IMAGINARY PART OF THE SEQUENCE.
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// THE TRANSFORM IS RETURNED IN X AND Y.
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// METHOD
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// FOR A GENERAL DISCUSSION OF THESE TRANSFORMS AND OF
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// THE FAST METHOD FOR COMPUTING THEM, SEE GENTLEMAN AND SANDE,
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// @FAST FOURIER TRANSFORMS - FOR FUN AND PROFIT,@ 1966 FALL JOINT
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// COMPUTER CONFERENCE.
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// THIS PROGRAM COMPUTES THIS FOR A COMPLEX SEQUENCE Z(T) OF LENGTH
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// N WHOSE ELEMENTS ARE STORED AT(X(I) , Y(I)) AND RETURNS THE
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// TRANSFORM COEFFICIENTS AT (X(I), Y(I)).
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// DESCRIPTION
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// AR1DFT IS A HIGHLY MODULAR ROUTINE CAPABLE OF COMPUTING IN PLACE
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// THE COMPLETE FINITE DISCRETE FOURIER TRANSFORM OF A ONE-
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// DIMENSIONAL SEQUENCE OF RATHER GENERAL LENGTH N.
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// THE MAIN ROUTINE , AR1DFT ITSELF, FACTORS N. IT THEN CALLS ON
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// ON GR 1D FT TO COMPUTE THE ACTUAL TRANSFORMS, USING THESE FACTORS.
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// THIS GR 1D FT DOES, CALLING AT EACH STAGE ON THE APPROPRIATE KERN
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// EL R2FTK, R4FTK, R8FTK, R16FTK, R3FTK, R5FTK, OR RPFTK TO PERFORM
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// THE COMPUTATIONS FOR THIS PASS OVER THE SEQUENCE, DEPENDING ON
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// WHETHER THE CORRESPONDING FACTOR IS 2, 4, 8, 16, 3, 5, OR SOME
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// MORE GENERAL PRIME P. WHEN GR1DFT IS FINISHED THE TRANSFORM IS
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// COMPUTED, HOWEVER, THE RESULTS ARE STORED IN "DIGITS REVERSED"
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// ORDER. AR1DFT THEREFORE, CALLS UPON GR 1S FS TO SORT THEM OUT.
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// TO RETURN TO THE FACTORIZATION, SINGLETON HAS POINTED OUT THAT
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// THE TRANSFORMS ARE MORE EFFICIENT IF THE SAMPLE SIZE N, IS OF THE
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// FORM B*A**2 AND B CONSISTS OF A SINGLE FACTOR. IN SUCH A CASE
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// IF WE PROCESS THE FACTORS IN THE ORDER ABA THEN
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// THE REORDERING CAN BE DONE AS FAST IN PLACE, AS WITH SCRATCH
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// STORAGE. BUT AS B BECOMES MORE COMPLICATED, THE COST OF THE DIGIT
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// REVERSING DUE TO B PART BECOMES VERY EXPENSIVE IF WE TRY TO DO IT
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// IN PLACE. IN SUCH A CASE IT MIGHT BE BETTER TO USE EXTRA STORAGE
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// A ROUTINE TO DO THIS IS, HOWEVER, NOT INCLUDED HERE.
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// ANOTHER FEATURE INFLUENCING THE FACTORIZATION IS THAT FOR ANY FIXED
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// FACTOR N WE CAN PREPARE A SPECIAL KERNEL WHICH WILL COMPUTE
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// THAT STAGE OF THE TRANSFORM MORE EFFICIENTLY THAN WOULD A KERNEL
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// FOR GENERAL FACTORS, ESPECIALLY IF THE GENERAL KERNEL HAD TO BE
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// APPLIED SEVERAL TIMES. FOR EXAMPLE, FACTORS OF 4 ARE MORE
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// EFFICIENT THAN FACTORS OF 2, FACTORS OF 8 MORE EFFICIENT THAN 4,ETC
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// ON THE OTHER HAND DIMINISHING RETURNS RAPIDLY SET IN, ESPECIALLY
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// SINCE THE LENGTH OF THE KERNEL FOR A SPECIAL CASE IS ROUGHLY
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// PROPORTIONAL TO THE FACTOR IT DEALS WITH. HENCE THESE PROBABLY ARE
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// ALL THE KERNELS WE WISH TO HAVE.
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// RESTRICTIONS.
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// AN UNFORTUNATE FEATURE OF THE SORTING PROBLEM IS THAT THE MOST
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// EFFICIENT WAY TO DO IT IS WITH NESTED DO LOOPS, ONE FOR EACH
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// FACTOR. THIS PUTS A RESTRICTION ON N AS TO HOW MANY FACTORS IT
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// CAN HAVE. CURRENTLY THE LIMIT IS 16, BUT THE LIMIT CAN BE READILY
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// RAISED IF NECESSARY.
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// A SECOND RESTRICTION OF THE PROGRAM IS THAT LOCAL STORAGE OF THE
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// THE ORDER P**2 IS REQUIRED BY THE GENERAL KERNEL RPFTK, SO SOME
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// LIMIT MUST BE SET ON P. CURRENTLY THIS IS 19, BUT IT CAN BE INCRE
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// INCREASED BY TRIVIAL CHANGES.
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// OTHER COMMENTS.
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//(1) THE ROUTINE IS ADAPTED TO CHECK WHETHER A GIVEN N WILL MEET THE
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// ABOVE FACTORING REQUIREMENTS AN, IF NOT, TO RETURN THE NEXT HIGHER
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// NUMBER, NX, SAY, WHICH WILL MEET THESE REQUIREMENTS.
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// THIS CAN BE ACCHIEVED BY A STATEMENT OF THE FORM
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// CALL FACTR(N,X,Y).
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// IF A DIFFERENT N, SAY NX, IS RETURNED THEN THE TRANSFORMS COULD BE
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// OBTAINED BY EXTENDING THE SIZE OF THE X-ARRAY AND Y-ARRAY TO NX,
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// AND SETTING X(I) = Y(I) = 0., FOR I = N+1, NX.
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//(2) IF THE SEQUENCE Z IS ONLY A REAL SEQUENCE, THEN THE IMAGINARY PART
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// Y(I)=0., THIS WILL RETURN THE COSINE TRANSFORM OF THE REAL SEQUENCE
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// IN X, AND THE SINE TRANSFORM IN Y.
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#define WANT_STREAM
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#define WANT_MATH
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#include "newmatap.h"
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#ifdef use_namespace
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namespace NEWMAT {
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#endif
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#ifdef DO_REPORT
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#define REPORT { static ExeCounter ExeCount(__LINE__,20); ++ExeCount; }
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#else
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#define REPORT {}
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#endif
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inline Real square(Real x) { return x*x; }
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inline int square(int x) { return x*x; }
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static void GR_1D_FS (int PTS, int N_SYM, int N_UN_SYM,
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const SimpleIntArray& SYM, int P_SYM, const SimpleIntArray& UN_SYM,
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Real* X, Real* Y);
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static void GR_1D_FT (int N, int N_FACTOR, const SimpleIntArray& FACTOR,
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Real* X, Real* Y);
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static void R_P_FTK (int N, int M, int P, Real* X, Real* Y);
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static void R_2_FTK (int N, int M, Real* X0, Real* Y0, Real* X1, Real* Y1);
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static void R_3_FTK (int N, int M, Real* X0, Real* Y0, Real* X1, Real* Y1,
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Real* X2, Real* Y2);
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static void R_4_FTK (int N, int M,
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Real* X0, Real* Y0, Real* X1, Real* Y1,
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Real* X2, Real* Y2, Real* X3, Real* Y3);
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static void R_5_FTK (int N, int M,
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Real* X0, Real* Y0, Real* X1, Real* Y1, Real* X2, Real* Y2,
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Real* X3, Real* Y3, Real* X4, Real* Y4);
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static void R_8_FTK (int N, int M,
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Real* X0, Real* Y0, Real* X1, Real* Y1,
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Real* X2, Real* Y2, Real* X3, Real* Y3,
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Real* X4, Real* Y4, Real* X5, Real* Y5,
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Real* X6, Real* Y6, Real* X7, Real* Y7);
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static void R_16_FTK (int N, int M,
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Real* X0, Real* Y0, Real* X1, Real* Y1,
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Real* X2, Real* Y2, Real* X3, Real* Y3,
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Real* X4, Real* Y4, Real* X5, Real* Y5,
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Real* X6, Real* Y6, Real* X7, Real* Y7,
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Real* X8, Real* Y8, Real* X9, Real* Y9,
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Real* X10, Real* Y10, Real* X11, Real* Y11,
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Real* X12, Real* Y12, Real* X13, Real* Y13,
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Real* X14, Real* Y14, Real* X15, Real* Y15);
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static int BitReverse(int x, int prod, int n, const SimpleIntArray& f);
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bool FFT_Controller::ar_1d_ft (int PTS, Real* X, Real *Y)
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{
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// ARBITRARY RADIX ONE DIMENSIONAL FOURIER TRANSFORM
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REPORT
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int F,J,N,NF,P,PMAX,P_SYM,P_TWO,Q,R,TWO_GRP;
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// NP is maximum number of squared factors allows PTS up to 2**32 at least
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// NQ is number of not-squared factors - increase if we increase PMAX
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const int NP = 16, NQ = 10;
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SimpleIntArray PP(NP), QQ(NQ);
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TWO_GRP=16; PMAX=19;
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// PMAX is the maximum factor size
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// TWO_GRP is the maximum power of 2 handled as a single factor
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// Doesn't take advantage of combining powers of 2 when calculating
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// number of factors
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if (PTS<=1) return true;
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N=PTS; P_SYM=1; F=2; P=0; Q=0;
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// P counts the number of squared factors
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// Q counts the number of the rest
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// R = 0 for no non-squared factors; 1 otherwise
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// FACTOR holds all the factors - non-squared ones in the middle
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// - length is 2*P+Q
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// SYM also holds all the factors but with the non-squared ones
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// multiplied together - length is 2*P+R
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// PP holds the values of the squared factors - length is P
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// QQ holds the values of the rest - length is Q
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// P_SYM holds the product of the squared factors
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// find the factors - load into PP and QQ
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while (N > 1)
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{
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bool fail = true;
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for (J=F; J<=PMAX; J++)
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if (N % J == 0) { fail = false; F=J; break; }
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if (fail || P >= NP || Q >= NQ) return false; // can't factor
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N /= F;
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if (N % F != 0) QQ[Q++] = F;
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else { N /= F; PP[P++] = F; P_SYM *= F; }
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}
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R = (Q == 0) ? 0 : 1; // R = 0 if no not-squared factors, 1 otherwise
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NF = 2*P + Q;
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SimpleIntArray FACTOR(NF + 1), SYM(2*P + R);
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FACTOR[NF] = 0; // we need this in the "combine powers of 2"
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// load into SYM and FACTOR
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for (J=0; J<P; J++)
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{ SYM[J]=FACTOR[J]=PP[P-1-J]; FACTOR[P+Q+J]=SYM[P+R+J]=PP[J]; }
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if (Q>0)
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{
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REPORT
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for (J=0; J<Q; J++) FACTOR[P+J]=QQ[J];
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SYM[P]=PTS/square(P_SYM);
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}
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// combine powers of 2
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P_TWO = 1;
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for (J=0; J < NF; J++)
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{
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if (FACTOR[J]!=2) continue;
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P_TWO=P_TWO*2; FACTOR[J]=1;
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if (P_TWO<TWO_GRP && FACTOR[J+1]==2) continue;
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FACTOR[J]=P_TWO; P_TWO=1;
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}
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if (P==0) R=0;
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if (Q<=1) Q=0;
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// do the analysis
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GR_1D_FT(PTS,NF,FACTOR,X,Y); // the transform
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GR_1D_FS(PTS,2*P+R,Q,SYM,P_SYM,QQ,X,Y); // the reshuffling
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return true;
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}
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static void GR_1D_FS (int PTS, int N_SYM, int N_UN_SYM,
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const SimpleIntArray& SYM, int P_SYM, const SimpleIntArray& UN_SYM,
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Real* X, Real* Y)
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{
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// GENERAL RADIX ONE DIMENSIONAL FOURIER SORT
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// PTS = number of points
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// N_SYM = length of SYM
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// N_UN_SYM = length of UN_SYM
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// SYM: squared factors + product of non-squared factors + squared factors
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// P_SYM = product of squared factors (each included only once)
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// UN_SYM: not-squared factors
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REPORT
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Real T;
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int JJ,KK,P_UN_SYM;
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// I have replaced the multiple for-loop used by Sande-Gentleman code
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// by the following code which does not limit the number of factors
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if (N_SYM > 0)
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{
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REPORT
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SimpleIntArray U(N_SYM);
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for(MultiRadixCounter MRC(N_SYM, SYM, U); !MRC.Finish(); ++MRC)
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{
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if (MRC.Swap())
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{
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int P = MRC.Reverse(); int JJ = MRC.Counter(); Real T;
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T=X[JJ]; X[JJ]=X[P]; X[P]=T; T=Y[JJ]; Y[JJ]=Y[P]; Y[P]=T;
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}
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}
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}
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int J,JL,K,L,M,MS;
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// UN_SYM contains the non-squared factors
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// I have replaced the Sande-Gentleman code as it runs into
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// integer overflow problems
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// My code (and theirs) would be improved by using a bit array
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// as suggested by Van Loan
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if (N_UN_SYM==0) { REPORT return; }
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P_UN_SYM=PTS/square(P_SYM); JL=(P_UN_SYM-3)*P_SYM; MS=P_UN_SYM*P_SYM;
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for (J = P_SYM; J<=JL; J+=P_SYM)
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{
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K=J;
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do K = P_SYM * BitReverse(K / P_SYM, P_UN_SYM, N_UN_SYM, UN_SYM);
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while (K<J);
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if (K!=J)
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{
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REPORT
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for (L=0; L<P_SYM; L++) for (M=L; M<PTS; M+=MS)
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{
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JJ=M+J; KK=M+K;
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T=X[JJ]; X[JJ]=X[KK]; X[KK]=T; T=Y[JJ]; Y[JJ]=Y[KK]; Y[KK]=T;
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}
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}
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}
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return;
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}
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static void GR_1D_FT (int N, int N_FACTOR, const SimpleIntArray& FACTOR,
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Real* X, Real* Y)
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{
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// GENERAL RADIX ONE DIMENSIONAL FOURIER TRANSFORM;
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REPORT
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int M = N;
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for (int i = 0; i < N_FACTOR; i++)
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{
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int P = FACTOR[i]; M /= P;
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switch(P)
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{
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case 1: REPORT break;
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case 2: REPORT R_2_FTK (N,M,X,Y,X+M,Y+M); break;
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case 3: REPORT R_3_FTK (N,M,X,Y,X+M,Y+M,X+2*M,Y+2*M); break;
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case 4: REPORT R_4_FTK (N,M,X,Y,X+M,Y+M,X+2*M,Y+2*M,X+3*M,Y+3*M); break;
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case 5:
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REPORT
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R_5_FTK (N,M,X,Y,X+M,Y+M,X+2*M,Y+2*M,X+3*M,Y+3*M,X+4*M,Y+4*M);
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break;
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case 8:
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REPORT
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R_8_FTK (N,M,X,Y,X+M,Y+M,X+2*M,Y+2*M,
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X+3*M,Y+3*M,X+4*M,Y+4*M,X+5*M,Y+5*M,
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X+6*M,Y+6*M,X+7*M,Y+7*M);
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break;
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case 16:
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REPORT
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R_16_FTK (N,M,X,Y,X+M,Y+M,X+2*M,Y+2*M,
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X+3*M,Y+3*M,X+4*M,Y+4*M,X+5*M,Y+5*M,
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X+6*M,Y+6*M,X+7*M,Y+7*M,X+8*M,Y+8*M,
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X+9*M,Y+9*M,X+10*M,Y+10*M,X+11*M,Y+11*M,
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X+12*M,Y+12*M,X+13*M,Y+13*M,X+14*M,Y+14*M,
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X+15*M,Y+15*M);
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break;
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default: REPORT R_P_FTK (N,M,P,X,Y); break;
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}
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}
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}
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static void R_P_FTK (int N, int M, int P, Real* X, Real* Y)
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// RADIX PRIME FOURIER TRANSFORM KERNEL;
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// X and Y are treated as M * P matrices with Fortran storage
|
||
|
{
|
||
|
REPORT
|
||
|
bool NO_FOLD,ZERO;
|
||
|
Real ANGLE,IS,IU,RS,RU,T,TWOPI,XT,YT;
|
||
|
int J,JJ,K0,K,M_OVER_2,MP,PM,PP,U,V;
|
||
|
|
||
|
Real AA [9][9], BB [9][9];
|
||
|
Real A [18], B [18], C [18], S [18];
|
||
|
Real IA [9], IB [9], RA [9], RB [9];
|
||
|
|
||
|
TWOPI=8.0*atan(1.0);
|
||
|
M_OVER_2=M/2+1; MP=M*P; PP=P/2; PM=P-1;
|
||
|
|
||
|
for (U=0; U<PP; U++)
|
||
|
{
|
||
|
ANGLE=TWOPI*Real(U+1)/Real(P);
|
||
|
JJ=P-U-2;
|
||
|
A[U]=cos(ANGLE); B[U]=sin(ANGLE);
|
||
|
A[JJ]=A[U]; B[JJ]= -B[U];
|
||
|
}
|
||
|
|
||
|
for (U=1; U<=PP; U++)
|
||
|
{
|
||
|
for (V=1; V<=PP; V++)
|
||
|
{ JJ=U*V-U*V/P*P; AA[V-1][U-1]=A[JJ-1]; BB[V-1][U-1]=B[JJ-1]; }
|
||
|
}
|
||
|
|
||
|
for (J=0; J<M_OVER_2; J++)
|
||
|
{
|
||
|
NO_FOLD = (J==0 || 2*J==M);
|
||
|
K0=J;
|
||
|
ANGLE=TWOPI*Real(J)/Real(MP); ZERO=ANGLE==0.0;
|
||
|
C[0]=cos(ANGLE); S[0]=sin(ANGLE);
|
||
|
for (U=1; U<PM; U++)
|
||
|
{
|
||
|
C[U]=C[U-1]*C[0]-S[U-1]*S[0];
|
||
|
S[U]=S[U-1]*C[0]+C[U-1]*S[0];
|
||
|
}
|
||
|
goto L700;
|
||
|
L500:
|
||
|
REPORT
|
||
|
if (NO_FOLD) { REPORT goto L1500; }
|
||
|
REPORT
|
||
|
NO_FOLD=true; K0=M-J;
|
||
|
for (U=0; U<PM; U++)
|
||
|
{ T=C[U]*A[U]+S[U]*B[U]; S[U]= -S[U]*A[U]+C[U]*B[U]; C[U]=T; }
|
||
|
L700:
|
||
|
REPORT
|
||
|
for (K=K0; K<N; K+=MP)
|
||
|
{
|
||
|
XT=X[K]; YT=Y[K];
|
||
|
for (U=1; U<=PP; U++)
|
||
|
{
|
||
|
RA[U-1]=XT; IA[U-1]=YT;
|
||
|
RB[U-1]=0.0; IB[U-1]=0.0;
|
||
|
}
|
||
|
for (U=1; U<=PP; U++)
|
||
|
{
|
||
|
JJ=P-U;
|
||
|
RS=X[K+M*U]+X[K+M*JJ]; IS=Y[K+M*U]+Y[K+M*JJ];
|
||
|
RU=X[K+M*U]-X[K+M*JJ]; IU=Y[K+M*U]-Y[K+M*JJ];
|
||
|
XT=XT+RS; YT=YT+IS;
|
||
|
for (V=0; V<PP; V++)
|
||
|
{
|
||
|
RA[V]=RA[V]+RS*AA[V][U-1]; IA[V]=IA[V]+IS*AA[V][U-1];
|
||
|
RB[V]=RB[V]+RU*BB[V][U-1]; IB[V]=IB[V]+IU*BB[V][U-1];
|
||
|
}
|
||
|
}
|
||
|
X[K]=XT; Y[K]=YT;
|
||
|
for (U=1; U<=PP; U++)
|
||
|
{
|
||
|
if (!ZERO)
|
||
|
{
|
||
|
REPORT
|
||
|
XT=RA[U-1]+IB[U-1]; YT=IA[U-1]-RB[U-1];
|
||
|
X[K+M*U]=XT*C[U-1]+YT*S[U-1]; Y[K+M*U]=YT*C[U-1]-XT*S[U-1];
|
||
|
JJ=P-U;
|
||
|
XT=RA[U-1]-IB[U-1]; YT=IA[U-1]+RB[U-1];
|
||
|
X[K+M*JJ]=XT*C[JJ-1]+YT*S[JJ-1];
|
||
|
Y[K+M*JJ]=YT*C[JJ-1]-XT*S[JJ-1];
|
||
|
}
|
||
|
else
|
||
|
{
|
||
|
REPORT
|
||
|
X[K+M*U]=RA[U-1]+IB[U-1]; Y[K+M*U]=IA[U-1]-RB[U-1];
|
||
|
JJ=P-U;
|
||
|
X[K+M*JJ]=RA[U-1]-IB[U-1]; Y[K+M*JJ]=IA[U-1]+RB[U-1];
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
goto L500;
|
||
|
L1500: ;
|
||
|
}
|
||
|
return;
|
||
|
}
|
||
|
|
||
|
static void R_2_FTK (int N, int M, Real* X0, Real* Y0, Real* X1, Real* Y1)
|
||
|
// RADIX TWO FOURIER TRANSFORM KERNEL;
|
||
|
{
|
||
|
REPORT
|
||
|
bool NO_FOLD,ZERO;
|
||
|
int J,K,K0,M2,M_OVER_2;
|
||
|
Real ANGLE,C,IS,IU,RS,RU,S,TWOPI;
|
||
|
|
||
|
M2=M*2; M_OVER_2=M/2+1;
|
||
|
TWOPI=8.0*atan(1.0);
|
||
|
|
||
|
for (J=0; J<M_OVER_2; J++)
|
||
|
{
|
||
|
NO_FOLD = (J==0 || 2*J==M);
|
||
|
K0=J;
|
||
|
ANGLE=TWOPI*Real(J)/Real(M2); ZERO=ANGLE==0.0;
|
||
|
C=cos(ANGLE); S=sin(ANGLE);
|
||
|
goto L200;
|
||
|
L100:
|
||
|
REPORT
|
||
|
if (NO_FOLD) { REPORT goto L600; }
|
||
|
REPORT
|
||
|
NO_FOLD=true; K0=M-J; C= -C;
|
||
|
L200:
|
||
|
REPORT
|
||
|
for (K=K0; K<N; K+=M2)
|
||
|
{
|
||
|
RS=X0[K]+X1[K]; IS=Y0[K]+Y1[K];
|
||
|
RU=X0[K]-X1[K]; IU=Y0[K]-Y1[K];
|
||
|
X0[K]=RS; Y0[K]=IS;
|
||
|
if (!ZERO) { X1[K]=RU*C+IU*S; Y1[K]=IU*C-RU*S; }
|
||
|
else { X1[K]=RU; Y1[K]=IU; }
|
||
|
}
|
||
|
goto L100;
|
||
|
L600: ;
|
||
|
}
|
||
|
|
||
|
return;
|
||
|
}
|
||
|
|
||
|
static void R_3_FTK (int N, int M, Real* X0, Real* Y0, Real* X1, Real* Y1,
|
||
|
Real* X2, Real* Y2)
|
||
|
// RADIX THREE FOURIER TRANSFORM KERNEL
|
||
|
{
|
||
|
REPORT
|
||
|
bool NO_FOLD,ZERO;
|
||
|
int J,K,K0,M3,M_OVER_2;
|
||
|
Real ANGLE,A,B,C1,C2,S1,S2,T,TWOPI;
|
||
|
Real I0,I1,I2,IA,IB,IS,R0,R1,R2,RA,RB,RS;
|
||
|
|
||
|
M3=M*3; M_OVER_2=M/2+1; TWOPI=8.0*atan(1.0);
|
||
|
A=cos(TWOPI/3.0); B=sin(TWOPI/3.0);
|
||
|
|
||
|
for (J=0; J<M_OVER_2; J++)
|
||
|
{
|
||
|
NO_FOLD = (J==0 || 2*J==M);
|
||
|
K0=J;
|
||
|
ANGLE=TWOPI*Real(J)/Real(M3); ZERO=ANGLE==0.0;
|
||
|
C1=cos(ANGLE); S1=sin(ANGLE);
|
||
|
C2=C1*C1-S1*S1; S2=S1*C1+C1*S1;
|
||
|
goto L200;
|
||
|
L100:
|
||
|
REPORT
|
||
|
if (NO_FOLD) { REPORT goto L600; }
|
||
|
REPORT
|
||
|
NO_FOLD=true; K0=M-J;
|
||
|
T=C1*A+S1*B; S1=C1*B-S1*A; C1=T;
|
||
|
T=C2*A-S2*B; S2= -C2*B-S2*A; C2=T;
|
||
|
L200:
|
||
|
REPORT
|
||
|
for (K=K0; K<N; K+=M3)
|
||
|
{
|
||
|
R0 = X0[K]; I0 = Y0[K];
|
||
|
RS=X1[K]+X2[K]; IS=Y1[K]+Y2[K];
|
||
|
X0[K]=R0+RS; Y0[K]=I0+IS;
|
||
|
RA=R0+RS*A; IA=I0+IS*A;
|
||
|
RB=(X1[K]-X2[K])*B; IB=(Y1[K]-Y2[K])*B;
|
||
|
if (!ZERO)
|
||
|
{
|
||
|
REPORT
|
||
|
R1=RA+IB; I1=IA-RB; R2=RA-IB; I2=IA+RB;
|
||
|
X1[K]=R1*C1+I1*S1; Y1[K]=I1*C1-R1*S1;
|
||
|
X2[K]=R2*C2+I2*S2; Y2[K]=I2*C2-R2*S2;
|
||
|
}
|
||
|
else { REPORT X1[K]=RA+IB; Y1[K]=IA-RB; X2[K]=RA-IB; Y2[K]=IA+RB; }
|
||
|
}
|
||
|
goto L100;
|
||
|
L600: ;
|
||
|
}
|
||
|
|
||
|
return;
|
||
|
}
|
||
|
|
||
|
static void R_4_FTK (int N, int M,
|
||
|
Real* X0, Real* Y0, Real* X1, Real* Y1,
|
||
|
Real* X2, Real* Y2, Real* X3, Real* Y3)
|
||
|
// RADIX FOUR FOURIER TRANSFORM KERNEL
|
||
|
{
|
||
|
REPORT
|
||
|
bool NO_FOLD,ZERO;
|
||
|
int J,K,K0,M4,M_OVER_2;
|
||
|
Real ANGLE,C1,C2,C3,S1,S2,S3,T,TWOPI;
|
||
|
Real I1,I2,I3,IS0,IS1,IU0,IU1,R1,R2,R3,RS0,RS1,RU0,RU1;
|
||
|
|
||
|
M4=M*4; M_OVER_2=M/2+1;
|
||
|
TWOPI=8.0*atan(1.0);
|
||
|
|
||
|
for (J=0; J<M_OVER_2; J++)
|
||
|
{
|
||
|
NO_FOLD = (J==0 || 2*J==M);
|
||
|
K0=J;
|
||
|
ANGLE=TWOPI*Real(J)/Real(M4); ZERO=ANGLE==0.0;
|
||
|
C1=cos(ANGLE); S1=sin(ANGLE);
|
||
|
C2=C1*C1-S1*S1; S2=S1*C1+C1*S1;
|
||
|
C3=C2*C1-S2*S1; S3=S2*C1+C2*S1;
|
||
|
goto L200;
|
||
|
L100:
|
||
|
REPORT
|
||
|
if (NO_FOLD) { REPORT goto L600; }
|
||
|
REPORT
|
||
|
NO_FOLD=true; K0=M-J;
|
||
|
T=C1; C1=S1; S1=T;
|
||
|
C2= -C2;
|
||
|
T=C3; C3= -S3; S3= -T;
|
||
|
L200:
|
||
|
REPORT
|
||
|
for (K=K0; K<N; K+=M4)
|
||
|
{
|
||
|
RS0=X0[K]+X2[K]; IS0=Y0[K]+Y2[K];
|
||
|
RU0=X0[K]-X2[K]; IU0=Y0[K]-Y2[K];
|
||
|
RS1=X1[K]+X3[K]; IS1=Y1[K]+Y3[K];
|
||
|
RU1=X1[K]-X3[K]; IU1=Y1[K]-Y3[K];
|
||
|
X0[K]=RS0+RS1; Y0[K]=IS0+IS1;
|
||
|
if (!ZERO)
|
||
|
{
|
||
|
REPORT
|
||
|
R1=RU0+IU1; I1=IU0-RU1;
|
||
|
R2=RS0-RS1; I2=IS0-IS1;
|
||
|
R3=RU0-IU1; I3=IU0+RU1;
|
||
|
X2[K]=R1*C1+I1*S1; Y2[K]=I1*C1-R1*S1;
|
||
|
X1[K]=R2*C2+I2*S2; Y1[K]=I2*C2-R2*S2;
|
||
|
X3[K]=R3*C3+I3*S3; Y3[K]=I3*C3-R3*S3;
|
||
|
}
|
||
|
else
|
||
|
{
|
||
|
REPORT
|
||
|
X2[K]=RU0+IU1; Y2[K]=IU0-RU1;
|
||
|
X1[K]=RS0-RS1; Y1[K]=IS0-IS1;
|
||
|
X3[K]=RU0-IU1; Y3[K]=IU0+RU1;
|
||
|
}
|
||
|
}
|
||
|
goto L100;
|
||
|
L600: ;
|
||
|
}
|
||
|
|
||
|
return;
|
||
|
}
|
||
|
|
||
|
static void R_5_FTK (int N, int M,
|
||
|
Real* X0, Real* Y0, Real* X1, Real* Y1, Real* X2, Real* Y2,
|
||
|
Real* X3, Real* Y3, Real* X4, Real* Y4)
|
||
|
// RADIX FIVE FOURIER TRANSFORM KERNEL
|
||
|
|
||
|
{
|
||
|
REPORT
|
||
|
bool NO_FOLD,ZERO;
|
||
|
int J,K,K0,M5,M_OVER_2;
|
||
|
Real ANGLE,A1,A2,B1,B2,C1,C2,C3,C4,S1,S2,S3,S4,T,TWOPI;
|
||
|
Real R0,R1,R2,R3,R4,RA1,RA2,RB1,RB2,RS1,RS2,RU1,RU2;
|
||
|
Real I0,I1,I2,I3,I4,IA1,IA2,IB1,IB2,IS1,IS2,IU1,IU2;
|
||
|
|
||
|
M5=M*5; M_OVER_2=M/2+1;
|
||
|
TWOPI=8.0*atan(1.0);
|
||
|
A1=cos(TWOPI/5.0); B1=sin(TWOPI/5.0);
|
||
|
A2=cos(2.0*TWOPI/5.0); B2=sin(2.0*TWOPI/5.0);
|
||
|
|
||
|
for (J=0; J<M_OVER_2; J++)
|
||
|
{
|
||
|
NO_FOLD = (J==0 || 2*J==M);
|
||
|
K0=J;
|
||
|
ANGLE=TWOPI*Real(J)/Real(M5); ZERO=ANGLE==0.0;
|
||
|
C1=cos(ANGLE); S1=sin(ANGLE);
|
||
|
C2=C1*C1-S1*S1; S2=S1*C1+C1*S1;
|
||
|
C3=C2*C1-S2*S1; S3=S2*C1+C2*S1;
|
||
|
C4=C2*C2-S2*S2; S4=S2*C2+C2*S2;
|
||
|
goto L200;
|
||
|
L100:
|
||
|
REPORT
|
||
|
if (NO_FOLD) { REPORT goto L600; }
|
||
|
REPORT
|
||
|
NO_FOLD=true; K0=M-J;
|
||
|
T=C1*A1+S1*B1; S1=C1*B1-S1*A1; C1=T;
|
||
|
T=C2*A2+S2*B2; S2=C2*B2-S2*A2; C2=T;
|
||
|
T=C3*A2-S3*B2; S3= -C3*B2-S3*A2; C3=T;
|
||
|
T=C4*A1-S4*B1; S4= -C4*B1-S4*A1; C4=T;
|
||
|
L200:
|
||
|
REPORT
|
||
|
for (K=K0; K<N; K+=M5)
|
||
|
{
|
||
|
R0=X0[K]; I0=Y0[K];
|
||
|
RS1=X1[K]+X4[K]; IS1=Y1[K]+Y4[K];
|
||
|
RU1=X1[K]-X4[K]; IU1=Y1[K]-Y4[K];
|
||
|
RS2=X2[K]+X3[K]; IS2=Y2[K]+Y3[K];
|
||
|
RU2=X2[K]-X3[K]; IU2=Y2[K]-Y3[K];
|
||
|
X0[K]=R0+RS1+RS2; Y0[K]=I0+IS1+IS2;
|
||
|
RA1=R0+RS1*A1+RS2*A2; IA1=I0+IS1*A1+IS2*A2;
|
||
|
RA2=R0+RS1*A2+RS2*A1; IA2=I0+IS1*A2+IS2*A1;
|
||
|
RB1=RU1*B1+RU2*B2; IB1=IU1*B1+IU2*B2;
|
||
|
RB2=RU1*B2-RU2*B1; IB2=IU1*B2-IU2*B1;
|
||
|
if (!ZERO)
|
||
|
{
|
||
|
REPORT
|
||
|
R1=RA1+IB1; I1=IA1-RB1;
|
||
|
R2=RA2+IB2; I2=IA2-RB2;
|
||
|
R3=RA2-IB2; I3=IA2+RB2;
|
||
|
R4=RA1-IB1; I4=IA1+RB1;
|
||
|
X1[K]=R1*C1+I1*S1; Y1[K]=I1*C1-R1*S1;
|
||
|
X2[K]=R2*C2+I2*S2; Y2[K]=I2*C2-R2*S2;
|
||
|
X3[K]=R3*C3+I3*S3; Y3[K]=I3*C3-R3*S3;
|
||
|
X4[K]=R4*C4+I4*S4; Y4[K]=I4*C4-R4*S4;
|
||
|
}
|
||
|
else
|
||
|
{
|
||
|
REPORT
|
||
|
X1[K]=RA1+IB1; Y1[K]=IA1-RB1;
|
||
|
X2[K]=RA2+IB2; Y2[K]=IA2-RB2;
|
||
|
X3[K]=RA2-IB2; Y3[K]=IA2+RB2;
|
||
|
X4[K]=RA1-IB1; Y4[K]=IA1+RB1;
|
||
|
}
|
||
|
}
|
||
|
goto L100;
|
||
|
L600: ;
|
||
|
}
|
||
|
|
||
|
return;
|
||
|
}
|
||
|
|
||
|
static void R_8_FTK (int N, int M,
|
||
|
Real* X0, Real* Y0, Real* X1, Real* Y1,
|
||
|
Real* X2, Real* Y2, Real* X3, Real* Y3,
|
||
|
Real* X4, Real* Y4, Real* X5, Real* Y5,
|
||
|
Real* X6, Real* Y6, Real* X7, Real* Y7)
|
||
|
// RADIX EIGHT FOURIER TRANSFORM KERNEL
|
||
|
{
|
||
|
REPORT
|
||
|
bool NO_FOLD,ZERO;
|
||
|
int J,K,K0,M8,M_OVER_2;
|
||
|
Real ANGLE,C1,C2,C3,C4,C5,C6,C7,E,S1,S2,S3,S4,S5,S6,S7,T,TWOPI;
|
||
|
Real R1,R2,R3,R4,R5,R6,R7,RS0,RS1,RS2,RS3,RU0,RU1,RU2,RU3;
|
||
|
Real I1,I2,I3,I4,I5,I6,I7,IS0,IS1,IS2,IS3,IU0,IU1,IU2,IU3;
|
||
|
Real RSS0,RSS1,RSU0,RSU1,RUS0,RUS1,RUU0,RUU1;
|
||
|
Real ISS0,ISS1,ISU0,ISU1,IUS0,IUS1,IUU0,IUU1;
|
||
|
|
||
|
M8=M*8; M_OVER_2=M/2+1;
|
||
|
TWOPI=8.0*atan(1.0); E=cos(TWOPI/8.0);
|
||
|
|
||
|
for (J=0;J<M_OVER_2;J++)
|
||
|
{
|
||
|
NO_FOLD= (J==0 || 2*J==M);
|
||
|
K0=J;
|
||
|
ANGLE=TWOPI*Real(J)/Real(M8); ZERO=ANGLE==0.0;
|
||
|
C1=cos(ANGLE); S1=sin(ANGLE);
|
||
|
C2=C1*C1-S1*S1; S2=C1*S1+S1*C1;
|
||
|
C3=C2*C1-S2*S1; S3=S2*C1+C2*S1;
|
||
|
C4=C2*C2-S2*S2; S4=S2*C2+C2*S2;
|
||
|
C5=C4*C1-S4*S1; S5=S4*C1+C4*S1;
|
||
|
C6=C4*C2-S4*S2; S6=S4*C2+C4*S2;
|
||
|
C7=C4*C3-S4*S3; S7=S4*C3+C4*S3;
|
||
|
goto L200;
|
||
|
L100:
|
||
|
REPORT
|
||
|
if (NO_FOLD) { REPORT goto L600; }
|
||
|
REPORT
|
||
|
NO_FOLD=true; K0=M-J;
|
||
|
T=(C1+S1)*E; S1=(C1-S1)*E; C1=T;
|
||
|
T=S2; S2=C2; C2=T;
|
||
|
T=(-C3+S3)*E; S3=(C3+S3)*E; C3=T;
|
||
|
C4= -C4;
|
||
|
T= -(C5+S5)*E; S5=(-C5+S5)*E; C5=T;
|
||
|
T= -S6; S6= -C6; C6=T;
|
||
|
T=(C7-S7)*E; S7= -(C7+S7)*E; C7=T;
|
||
|
L200:
|
||
|
REPORT
|
||
|
for (K=K0; K<N; K+=M8)
|
||
|
{
|
||
|
RS0=X0[K]+X4[K]; IS0=Y0[K]+Y4[K];
|
||
|
RU0=X0[K]-X4[K]; IU0=Y0[K]-Y4[K];
|
||
|
RS1=X1[K]+X5[K]; IS1=Y1[K]+Y5[K];
|
||
|
RU1=X1[K]-X5[K]; IU1=Y1[K]-Y5[K];
|
||
|
RS2=X2[K]+X6[K]; IS2=Y2[K]+Y6[K];
|
||
|
RU2=X2[K]-X6[K]; IU2=Y2[K]-Y6[K];
|
||
|
RS3=X3[K]+X7[K]; IS3=Y3[K]+Y7[K];
|
||
|
RU3=X3[K]-X7[K]; IU3=Y3[K]-Y7[K];
|
||
|
RSS0=RS0+RS2; ISS0=IS0+IS2;
|
||
|
RSU0=RS0-RS2; ISU0=IS0-IS2;
|
||
|
RSS1=RS1+RS3; ISS1=IS1+IS3;
|
||
|
RSU1=RS1-RS3; ISU1=IS1-IS3;
|
||
|
RUS0=RU0-IU2; IUS0=IU0+RU2;
|
||
|
RUU0=RU0+IU2; IUU0=IU0-RU2;
|
||
|
RUS1=RU1-IU3; IUS1=IU1+RU3;
|
||
|
RUU1=RU1+IU3; IUU1=IU1-RU3;
|
||
|
T=(RUS1+IUS1)*E; IUS1=(IUS1-RUS1)*E; RUS1=T;
|
||
|
T=(RUU1+IUU1)*E; IUU1=(IUU1-RUU1)*E; RUU1=T;
|
||
|
X0[K]=RSS0+RSS1; Y0[K]=ISS0+ISS1;
|
||
|
if (!ZERO)
|
||
|
{
|
||
|
REPORT
|
||
|
R1=RUU0+RUU1; I1=IUU0+IUU1;
|
||
|
R2=RSU0+ISU1; I2=ISU0-RSU1;
|
||
|
R3=RUS0+IUS1; I3=IUS0-RUS1;
|
||
|
R4=RSS0-RSS1; I4=ISS0-ISS1;
|
||
|
R5=RUU0-RUU1; I5=IUU0-IUU1;
|
||
|
R6=RSU0-ISU1; I6=ISU0+RSU1;
|
||
|
R7=RUS0-IUS1; I7=IUS0+RUS1;
|
||
|
X4[K]=R1*C1+I1*S1; Y4[K]=I1*C1-R1*S1;
|
||
|
X2[K]=R2*C2+I2*S2; Y2[K]=I2*C2-R2*S2;
|
||
|
X6[K]=R3*C3+I3*S3; Y6[K]=I3*C3-R3*S3;
|
||
|
X1[K]=R4*C4+I4*S4; Y1[K]=I4*C4-R4*S4;
|
||
|
X5[K]=R5*C5+I5*S5; Y5[K]=I5*C5-R5*S5;
|
||
|
X3[K]=R6*C6+I6*S6; Y3[K]=I6*C6-R6*S6;
|
||
|
X7[K]=R7*C7+I7*S7; Y7[K]=I7*C7-R7*S7;
|
||
|
}
|
||
|
else
|
||
|
{
|
||
|
REPORT
|
||
|
X4[K]=RUU0+RUU1; Y4[K]=IUU0+IUU1;
|
||
|
X2[K]=RSU0+ISU1; Y2[K]=ISU0-RSU1;
|
||
|
X6[K]=RUS0+IUS1; Y6[K]=IUS0-RUS1;
|
||
|
X1[K]=RSS0-RSS1; Y1[K]=ISS0-ISS1;
|
||
|
X5[K]=RUU0-RUU1; Y5[K]=IUU0-IUU1;
|
||
|
X3[K]=RSU0-ISU1; Y3[K]=ISU0+RSU1;
|
||
|
X7[K]=RUS0-IUS1; Y7[K]=IUS0+RUS1;
|
||
|
}
|
||
|
}
|
||
|
goto L100;
|
||
|
L600: ;
|
||
|
}
|
||
|
|
||
|
return;
|
||
|
}
|
||
|
|
||
|
static void R_16_FTK (int N, int M,
|
||
|
Real* X0, Real* Y0, Real* X1, Real* Y1,
|
||
|
Real* X2, Real* Y2, Real* X3, Real* Y3,
|
||
|
Real* X4, Real* Y4, Real* X5, Real* Y5,
|
||
|
Real* X6, Real* Y6, Real* X7, Real* Y7,
|
||
|
Real* X8, Real* Y8, Real* X9, Real* Y9,
|
||
|
Real* X10, Real* Y10, Real* X11, Real* Y11,
|
||
|
Real* X12, Real* Y12, Real* X13, Real* Y13,
|
||
|
Real* X14, Real* Y14, Real* X15, Real* Y15)
|
||
|
// RADIX SIXTEEN FOURIER TRANSFORM KERNEL
|
||
|
{
|
||
|
REPORT
|
||
|
bool NO_FOLD,ZERO;
|
||
|
int J,K,K0,M16,M_OVER_2;
|
||
|
Real ANGLE,EI1,ER1,E2,EI3,ER3,EI5,ER5,T,TWOPI;
|
||
|
Real RS0,RS1,RS2,RS3,RS4,RS5,RS6,RS7;
|
||
|
Real IS0,IS1,IS2,IS3,IS4,IS5,IS6,IS7;
|
||
|
Real RU0,RU1,RU2,RU3,RU4,RU5,RU6,RU7;
|
||
|
Real IU0,IU1,IU2,IU3,IU4,IU5,IU6,IU7;
|
||
|
Real RUS0,RUS1,RUS2,RUS3,RUU0,RUU1,RUU2,RUU3;
|
||
|
Real ISS0,ISS1,ISS2,ISS3,ISU0,ISU1,ISU2,ISU3;
|
||
|
Real RSS0,RSS1,RSS2,RSS3,RSU0,RSU1,RSU2,RSU3;
|
||
|
Real IUS0,IUS1,IUS2,IUS3,IUU0,IUU1,IUU2,IUU3;
|
||
|
Real RSSS0,RSSS1,RSSU0,RSSU1,RSUS0,RSUS1,RSUU0,RSUU1;
|
||
|
Real ISSS0,ISSS1,ISSU0,ISSU1,ISUS0,ISUS1,ISUU0,ISUU1;
|
||
|
Real RUSS0,RUSS1,RUSU0,RUSU1,RUUS0,RUUS1,RUUU0,RUUU1;
|
||
|
Real IUSS0,IUSS1,IUSU0,IUSU1,IUUS0,IUUS1,IUUU0,IUUU1;
|
||
|
Real R1,R2,R3,R4,R5,R6,R7,R8,R9,R10,R11,R12,R13,R14,R15;
|
||
|
Real I1,I2,I3,I4,I5,I6,I7,I8,I9,I10,I11,I12,I13,I14,I15;
|
||
|
Real C1,C2,C3,C4,C5,C6,C7,C8,C9,C10,C11,C12,C13,C14,C15;
|
||
|
Real S1,S2,S3,S4,S5,S6,S7,S8,S9,S10,S11,S12,S13,S14,S15;
|
||
|
|
||
|
M16=M*16; M_OVER_2=M/2+1;
|
||
|
TWOPI=8.0*atan(1.0);
|
||
|
ER1=cos(TWOPI/16.0); EI1=sin(TWOPI/16.0);
|
||
|
E2=cos(TWOPI/8.0);
|
||
|
ER3=cos(3.0*TWOPI/16.0); EI3=sin(3.0*TWOPI/16.0);
|
||
|
ER5=cos(5.0*TWOPI/16.0); EI5=sin(5.0*TWOPI/16.0);
|
||
|
|
||
|
for (J=0; J<M_OVER_2; J++)
|
||
|
{
|
||
|
NO_FOLD = (J==0 || 2*J==M);
|
||
|
K0=J;
|
||
|
ANGLE=TWOPI*Real(J)/Real(M16);
|
||
|
ZERO=ANGLE==0.0;
|
||
|
C1=cos(ANGLE); S1=sin(ANGLE);
|
||
|
C2=C1*C1-S1*S1; S2=C1*S1+S1*C1;
|
||
|
C3=C2*C1-S2*S1; S3=S2*C1+C2*S1;
|
||
|
C4=C2*C2-S2*S2; S4=S2*C2+C2*S2;
|
||
|
C5=C4*C1-S4*S1; S5=S4*C1+C4*S1;
|
||
|
C6=C4*C2-S4*S2; S6=S4*C2+C4*S2;
|
||
|
C7=C4*C3-S4*S3; S7=S4*C3+C4*S3;
|
||
|
C8=C4*C4-S4*S4; S8=C4*S4+S4*C4;
|
||
|
C9=C8*C1-S8*S1; S9=S8*C1+C8*S1;
|
||
|
C10=C8*C2-S8*S2; S10=S8*C2+C8*S2;
|
||
|
C11=C8*C3-S8*S3; S11=S8*C3+C8*S3;
|
||
|
C12=C8*C4-S8*S4; S12=S8*C4+C8*S4;
|
||
|
C13=C8*C5-S8*S5; S13=S8*C5+C8*S5;
|
||
|
C14=C8*C6-S8*S6; S14=S8*C6+C8*S6;
|
||
|
C15=C8*C7-S8*S7; S15=S8*C7+C8*S7;
|
||
|
goto L200;
|
||
|
L100:
|
||
|
REPORT
|
||
|
if (NO_FOLD) { REPORT goto L600; }
|
||
|
REPORT
|
||
|
NO_FOLD=true; K0=M-J;
|
||
|
T=C1*ER1+S1*EI1; S1= -S1*ER1+C1*EI1; C1=T;
|
||
|
T=(C2+S2)*E2; S2=(C2-S2)*E2; C2=T;
|
||
|
T=C3*ER3+S3*EI3; S3= -S3*ER3+C3*EI3; C3=T;
|
||
|
T=S4; S4=C4; C4=T;
|
||
|
T=S5*ER1-C5*EI1; S5=C5*ER1+S5*EI1; C5=T;
|
||
|
T=(-C6+S6)*E2; S6=(C6+S6)*E2; C6=T;
|
||
|
T=S7*ER3-C7*EI3; S7=C7*ER3+S7*EI3; C7=T;
|
||
|
C8= -C8;
|
||
|
T= -(C9*ER1+S9*EI1); S9=S9*ER1-C9*EI1; C9=T;
|
||
|
T= -(C10+S10)*E2; S10=(-C10+S10)*E2; C10=T;
|
||
|
T= -(C11*ER3+S11*EI3); S11=S11*ER3-C11*EI3; C11=T;
|
||
|
T= -S12; S12= -C12; C12=T;
|
||
|
T= -S13*ER1+C13*EI1; S13= -(C13*ER1+S13*EI1); C13=T;
|
||
|
T=(C14-S14)*E2; S14= -(C14+S14)*E2; C14=T;
|
||
|
T= -S15*ER3+C15*EI3; S15= -(C15*ER3+S15*EI3); C15=T;
|
||
|
L200:
|
||
|
REPORT
|
||
|
for (K=K0; K<N; K+=M16)
|
||
|
{
|
||
|
RS0=X0[K]+X8[K]; IS0=Y0[K]+Y8[K];
|
||
|
RU0=X0[K]-X8[K]; IU0=Y0[K]-Y8[K];
|
||
|
RS1=X1[K]+X9[K]; IS1=Y1[K]+Y9[K];
|
||
|
RU1=X1[K]-X9[K]; IU1=Y1[K]-Y9[K];
|
||
|
RS2=X2[K]+X10[K]; IS2=Y2[K]+Y10[K];
|
||
|
RU2=X2[K]-X10[K]; IU2=Y2[K]-Y10[K];
|
||
|
RS3=X3[K]+X11[K]; IS3=Y3[K]+Y11[K];
|
||
|
RU3=X3[K]-X11[K]; IU3=Y3[K]-Y11[K];
|
||
|
RS4=X4[K]+X12[K]; IS4=Y4[K]+Y12[K];
|
||
|
RU4=X4[K]-X12[K]; IU4=Y4[K]-Y12[K];
|
||
|
RS5=X5[K]+X13[K]; IS5=Y5[K]+Y13[K];
|
||
|
RU5=X5[K]-X13[K]; IU5=Y5[K]-Y13[K];
|
||
|
RS6=X6[K]+X14[K]; IS6=Y6[K]+Y14[K];
|
||
|
RU6=X6[K]-X14[K]; IU6=Y6[K]-Y14[K];
|
||
|
RS7=X7[K]+X15[K]; IS7=Y7[K]+Y15[K];
|
||
|
RU7=X7[K]-X15[K]; IU7=Y7[K]-Y15[K];
|
||
|
RSS0=RS0+RS4; ISS0=IS0+IS4;
|
||
|
RSS1=RS1+RS5; ISS1=IS1+IS5;
|
||
|
RSS2=RS2+RS6; ISS2=IS2+IS6;
|
||
|
RSS3=RS3+RS7; ISS3=IS3+IS7;
|
||
|
RSU0=RS0-RS4; ISU0=IS0-IS4;
|
||
|
RSU1=RS1-RS5; ISU1=IS1-IS5;
|
||
|
RSU2=RS2-RS6; ISU2=IS2-IS6;
|
||
|
RSU3=RS3-RS7; ISU3=IS3-IS7;
|
||
|
RUS0=RU0-IU4; IUS0=IU0+RU4;
|
||
|
RUS1=RU1-IU5; IUS1=IU1+RU5;
|
||
|
RUS2=RU2-IU6; IUS2=IU2+RU6;
|
||
|
RUS3=RU3-IU7; IUS3=IU3+RU7;
|
||
|
RUU0=RU0+IU4; IUU0=IU0-RU4;
|
||
|
RUU1=RU1+IU5; IUU1=IU1-RU5;
|
||
|
RUU2=RU2+IU6; IUU2=IU2-RU6;
|
||
|
RUU3=RU3+IU7; IUU3=IU3-RU7;
|
||
|
T=(RSU1+ISU1)*E2; ISU1=(ISU1-RSU1)*E2; RSU1=T;
|
||
|
T=(RSU3+ISU3)*E2; ISU3=(ISU3-RSU3)*E2; RSU3=T;
|
||
|
T=RUS1*ER3+IUS1*EI3; IUS1=IUS1*ER3-RUS1*EI3; RUS1=T;
|
||
|
T=(RUS2+IUS2)*E2; IUS2=(IUS2-RUS2)*E2; RUS2=T;
|
||
|
T=RUS3*ER5+IUS3*EI5; IUS3=IUS3*ER5-RUS3*EI5; RUS3=T;
|
||
|
T=RUU1*ER1+IUU1*EI1; IUU1=IUU1*ER1-RUU1*EI1; RUU1=T;
|
||
|
T=(RUU2+IUU2)*E2; IUU2=(IUU2-RUU2)*E2; RUU2=T;
|
||
|
T=RUU3*ER3+IUU3*EI3; IUU3=IUU3*ER3-RUU3*EI3; RUU3=T;
|
||
|
RSSS0=RSS0+RSS2; ISSS0=ISS0+ISS2;
|
||
|
RSSS1=RSS1+RSS3; ISSS1=ISS1+ISS3;
|
||
|
RSSU0=RSS0-RSS2; ISSU0=ISS0-ISS2;
|
||
|
RSSU1=RSS1-RSS3; ISSU1=ISS1-ISS3;
|
||
|
RSUS0=RSU0-ISU2; ISUS0=ISU0+RSU2;
|
||
|
RSUS1=RSU1-ISU3; ISUS1=ISU1+RSU3;
|
||
|
RSUU0=RSU0+ISU2; ISUU0=ISU0-RSU2;
|
||
|
RSUU1=RSU1+ISU3; ISUU1=ISU1-RSU3;
|
||
|
RUSS0=RUS0-IUS2; IUSS0=IUS0+RUS2;
|
||
|
RUSS1=RUS1-IUS3; IUSS1=IUS1+RUS3;
|
||
|
RUSU0=RUS0+IUS2; IUSU0=IUS0-RUS2;
|
||
|
RUSU1=RUS1+IUS3; IUSU1=IUS1-RUS3;
|
||
|
RUUS0=RUU0+RUU2; IUUS0=IUU0+IUU2;
|
||
|
RUUS1=RUU1+RUU3; IUUS1=IUU1+IUU3;
|
||
|
RUUU0=RUU0-RUU2; IUUU0=IUU0-IUU2;
|
||
|
RUUU1=RUU1-RUU3; IUUU1=IUU1-IUU3;
|
||
|
X0[K]=RSSS0+RSSS1; Y0[K]=ISSS0+ISSS1;
|
||
|
if (!ZERO)
|
||
|
{
|
||
|
REPORT
|
||
|
R1=RUUS0+RUUS1; I1=IUUS0+IUUS1;
|
||
|
R2=RSUU0+RSUU1; I2=ISUU0+ISUU1;
|
||
|
R3=RUSU0+RUSU1; I3=IUSU0+IUSU1;
|
||
|
R4=RSSU0+ISSU1; I4=ISSU0-RSSU1;
|
||
|
R5=RUUU0+IUUU1; I5=IUUU0-RUUU1;
|
||
|
R6=RSUS0+ISUS1; I6=ISUS0-RSUS1;
|
||
|
R7=RUSS0+IUSS1; I7=IUSS0-RUSS1;
|
||
|
R8=RSSS0-RSSS1; I8=ISSS0-ISSS1;
|
||
|
R9=RUUS0-RUUS1; I9=IUUS0-IUUS1;
|
||
|
R10=RSUU0-RSUU1; I10=ISUU0-ISUU1;
|
||
|
R11=RUSU0-RUSU1; I11=IUSU0-IUSU1;
|
||
|
R12=RSSU0-ISSU1; I12=ISSU0+RSSU1;
|
||
|
R13=RUUU0-IUUU1; I13=IUUU0+RUUU1;
|
||
|
R14=RSUS0-ISUS1; I14=ISUS0+RSUS1;
|
||
|
R15=RUSS0-IUSS1; I15=IUSS0+RUSS1;
|
||
|
X8[K]=R1*C1+I1*S1; Y8[K]=I1*C1-R1*S1;
|
||
|
X4[K]=R2*C2+I2*S2; Y4[K]=I2*C2-R2*S2;
|
||
|
X12[K]=R3*C3+I3*S3; Y12[K]=I3*C3-R3*S3;
|
||
|
X2[K]=R4*C4+I4*S4; Y2[K]=I4*C4-R4*S4;
|
||
|
X10[K]=R5*C5+I5*S5; Y10[K]=I5*C5-R5*S5;
|
||
|
X6[K]=R6*C6+I6*S6; Y6[K]=I6*C6-R6*S6;
|
||
|
X14[K]=R7*C7+I7*S7; Y14[K]=I7*C7-R7*S7;
|
||
|
X1[K]=R8*C8+I8*S8; Y1[K]=I8*C8-R8*S8;
|
||
|
X9[K]=R9*C9+I9*S9; Y9[K]=I9*C9-R9*S9;
|
||
|
X5[K]=R10*C10+I10*S10; Y5[K]=I10*C10-R10*S10;
|
||
|
X13[K]=R11*C11+I11*S11; Y13[K]=I11*C11-R11*S11;
|
||
|
X3[K]=R12*C12+I12*S12; Y3[K]=I12*C12-R12*S12;
|
||
|
X11[K]=R13*C13+I13*S13; Y11[K]=I13*C13-R13*S13;
|
||
|
X7[K]=R14*C14+I14*S14; Y7[K]=I14*C14-R14*S14;
|
||
|
X15[K]=R15*C15+I15*S15; Y15[K]=I15*C15-R15*S15;
|
||
|
}
|
||
|
else
|
||
|
{
|
||
|
REPORT
|
||
|
X8[K]=RUUS0+RUUS1; Y8[K]=IUUS0+IUUS1;
|
||
|
X4[K]=RSUU0+RSUU1; Y4[K]=ISUU0+ISUU1;
|
||
|
X12[K]=RUSU0+RUSU1; Y12[K]=IUSU0+IUSU1;
|
||
|
X2[K]=RSSU0+ISSU1; Y2[K]=ISSU0-RSSU1;
|
||
|
X10[K]=RUUU0+IUUU1; Y10[K]=IUUU0-RUUU1;
|
||
|
X6[K]=RSUS0+ISUS1; Y6[K]=ISUS0-RSUS1;
|
||
|
X14[K]=RUSS0+IUSS1; Y14[K]=IUSS0-RUSS1;
|
||
|
X1[K]=RSSS0-RSSS1; Y1[K]=ISSS0-ISSS1;
|
||
|
X9[K]=RUUS0-RUUS1; Y9[K]=IUUS0-IUUS1;
|
||
|
X5[K]=RSUU0-RSUU1; Y5[K]=ISUU0-ISUU1;
|
||
|
X13[K]=RUSU0-RUSU1; Y13[K]=IUSU0-IUSU1;
|
||
|
X3[K]=RSSU0-ISSU1; Y3[K]=ISSU0+RSSU1;
|
||
|
X11[K]=RUUU0-IUUU1; Y11[K]=IUUU0+RUUU1;
|
||
|
X7[K]=RSUS0-ISUS1; Y7[K]=ISUS0+RSUS1;
|
||
|
X15[K]=RUSS0-IUSS1; Y15[K]=IUSS0+RUSS1;
|
||
|
}
|
||
|
}
|
||
|
goto L100;
|
||
|
L600: ;
|
||
|
}
|
||
|
|
||
|
return;
|
||
|
}
|
||
|
|
||
|
// can the number of points be factorised sufficiently
|
||
|
// for the fft to run
|
||
|
|
||
|
bool FFT_Controller::CanFactor(int PTS)
|
||
|
{
|
||
|
REPORT
|
||
|
const int NP = 16, NQ = 10, PMAX=19;
|
||
|
|
||
|
if (PTS<=1) { REPORT return true; }
|
||
|
|
||
|
int N = PTS, F = 2, P = 0, Q = 0;
|
||
|
|
||
|
while (N > 1)
|
||
|
{
|
||
|
bool fail = true;
|
||
|
for (int J = F; J <= PMAX; J++)
|
||
|
if (N % J == 0) { fail = false; F=J; break; }
|
||
|
if (fail || P >= NP || Q >= NQ) { REPORT return false; }
|
||
|
N /= F;
|
||
|
if (N % F != 0) Q++; else { N /= F; P++; }
|
||
|
}
|
||
|
|
||
|
return true; // can factorise
|
||
|
|
||
|
}
|
||
|
|
||
|
bool FFT_Controller::OnlyOldFFT; // static variable
|
||
|
|
||
|
// **************************** multi radix counter **********************
|
||
|
|
||
|
MultiRadixCounter::MultiRadixCounter(int nx, const SimpleIntArray& rx,
|
||
|
SimpleIntArray& vx)
|
||
|
: Radix(rx), Value(vx), n(nx), reverse(0),
|
||
|
product(1), counter(0), finish(false)
|
||
|
{
|
||
|
REPORT for (int k = 0; k < n; k++) { Value[k] = 0; product *= Radix[k]; }
|
||
|
}
|
||
|
|
||
|
void MultiRadixCounter::operator++()
|
||
|
{
|
||
|
REPORT
|
||
|
counter++; int p = product;
|
||
|
for (int k = 0; k < n; k++)
|
||
|
{
|
||
|
Value[k]++; int p1 = p / Radix[k]; reverse += p1;
|
||
|
if (Value[k] == Radix[k]) { REPORT Value[k] = 0; reverse -= p; p = p1; }
|
||
|
else { REPORT return; }
|
||
|
}
|
||
|
finish = true;
|
||
|
}
|
||
|
|
||
|
|
||
|
static int BitReverse(int x, int prod, int n, const SimpleIntArray& f)
|
||
|
{
|
||
|
// x = c[0]+f[0]*(c[1]+f[1]*(c[2]+...
|
||
|
// return c[n-1]+f[n-1]*(c[n-2]+f[n-2]*(c[n-3]+...
|
||
|
// prod is the product of the f[i]
|
||
|
// n is the number of f[i] (don't assume f has the correct length)
|
||
|
|
||
|
REPORT
|
||
|
const int* d = f.Data() + n; int sum = 0; int q = 1;
|
||
|
while (n--)
|
||
|
{
|
||
|
prod /= *(--d);
|
||
|
int c = x / prod; x-= c * prod;
|
||
|
sum += q * c; q *= *d;
|
||
|
}
|
||
|
return sum;
|
||
|
}
|
||
|
|
||
|
|
||
|
#ifdef use_namespace
|
||
|
}
|
||
|
#endif
|
||
|
|
||
|
|