source: trunk/sources/ALGLIB/ftbase.cs @ 2575

/*************************************************************************
Copyright (c) 2009, Sergey Bochkanov (ALGLIB project).

>>> SOURCE LICENSE >>>
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 (www.fsf.org); 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.

A copy of the GNU General Public License is available at
http://www.fsf.org/licensing/licenses

>>> END OF LICENSE >>>
*************************************************************************/

using System;

namespace alglib
{
    public class ftbase
    {
        public struct ftplan
        {
            public int[] plan;
            public double[] precomputed;
            public double[] tmpbuf;
            public double[] stackbuf;
        };




        public const int ftbaseplanentrysize = 8;
        public const int ftbasecffttask = 0;
        public const int ftbaserfhttask = 1;
        public const int ftbaserffttask = 2;
        public const int fftcooleytukeyplan = 0;
        public const int fftbluesteinplan = 1;
        public const int fftcodeletplan = 2;
        public const int fhtcooleytukeyplan = 3;
        public const int fhtcodeletplan = 4;
        public const int fftrealcooleytukeyplan = 5;
        public const int fftemptyplan = 6;
        public const int fhtn2plan = 999;
        public const int ftbaseupdatetw = 4;
        public const int ftbasecodeletmax = 5;
        public const int ftbasecodeletrecommended = 5;
        public const double ftbaseinefficiencyfactor = 1.3;
        public const int ftbasemaxsmoothfactor = 5;


        /*************************************************************************
        This subroutine generates FFT plan - a decomposition of a N-length FFT to
        the more simpler operations. Plan consists of the root entry and the child
        entries.

        Subroutine parameters:
            N               task size
            
        Output parameters:
            Plan            plan

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        public static void ftbasegeneratecomplexfftplan(int n,
            ref ftplan plan)
        {
            int planarraysize = 0;
            int plansize = 0;
            int precomputedsize = 0;
            int tmpmemsize = 0;
            int stackmemsize = 0;
            int stackptr = 0;

            planarraysize = 1;
            plansize = 0;
            precomputedsize = 0;
            stackmemsize = 0;
            stackptr = 0;
            tmpmemsize = 2*n;
            plan.plan = new int[planarraysize];
            ftbasegenerateplanrec(n, ftbasecffttask, ref plan, ref plansize, ref precomputedsize, ref planarraysize, ref tmpmemsize, ref stackmemsize, stackptr);
            System.Diagnostics.Debug.Assert(stackptr==0, "Internal error in FTBaseGenerateComplexFFTPlan: stack ptr!");
            plan.stackbuf = new double[Math.Max(stackmemsize, 1)];
            plan.tmpbuf = new double[Math.Max(tmpmemsize, 1)];
            plan.precomputed = new double[Math.Max(precomputedsize, 1)];
            stackptr = 0;
            ftbaseprecomputeplanrec(ref plan, 0, stackptr);
            System.Diagnostics.Debug.Assert(stackptr==0, "Internal error in FTBaseGenerateComplexFFTPlan: stack ptr!");
        }


        /*************************************************************************
        Generates real FFT plan
        *************************************************************************/
        public static void ftbasegeneraterealfftplan(int n,
            ref ftplan plan)
        {
            int planarraysize = 0;
            int plansize = 0;
            int precomputedsize = 0;
            int tmpmemsize = 0;
            int stackmemsize = 0;
            int stackptr = 0;

            planarraysize = 1;
            plansize = 0;
            precomputedsize = 0;
            stackmemsize = 0;
            stackptr = 0;
            tmpmemsize = 2*n;
            plan.plan = new int[planarraysize];
            ftbasegenerateplanrec(n, ftbaserffttask, ref plan, ref plansize, ref precomputedsize, ref planarraysize, ref tmpmemsize, ref stackmemsize, stackptr);
            System.Diagnostics.Debug.Assert(stackptr==0, "Internal error in FTBaseGenerateRealFFTPlan: stack ptr!");
            plan.stackbuf = new double[Math.Max(stackmemsize, 1)];
            plan.tmpbuf = new double[Math.Max(tmpmemsize, 1)];
            plan.precomputed = new double[Math.Max(precomputedsize, 1)];
            stackptr = 0;
            ftbaseprecomputeplanrec(ref plan, 0, stackptr);
            System.Diagnostics.Debug.Assert(stackptr==0, "Internal error in FTBaseGenerateRealFFTPlan: stack ptr!");
        }


        /*************************************************************************
        Generates real FHT plan
        *************************************************************************/
        public static void ftbasegeneraterealfhtplan(int n,
            ref ftplan plan)
        {
            int planarraysize = 0;
            int plansize = 0;
            int precomputedsize = 0;
            int tmpmemsize = 0;
            int stackmemsize = 0;
            int stackptr = 0;

            planarraysize = 1;
            plansize = 0;
            precomputedsize = 0;
            stackmemsize = 0;
            stackptr = 0;
            tmpmemsize = n;
            plan.plan = new int[planarraysize];
            ftbasegenerateplanrec(n, ftbaserfhttask, ref plan, ref plansize, ref precomputedsize, ref planarraysize, ref tmpmemsize, ref stackmemsize, stackptr);
            System.Diagnostics.Debug.Assert(stackptr==0, "Internal error in FTBaseGenerateRealFHTPlan: stack ptr!");
            plan.stackbuf = new double[Math.Max(stackmemsize, 1)];
            plan.tmpbuf = new double[Math.Max(tmpmemsize, 1)];
            plan.precomputed = new double[Math.Max(precomputedsize, 1)];
            stackptr = 0;
            ftbaseprecomputeplanrec(ref plan, 0, stackptr);
            System.Diagnostics.Debug.Assert(stackptr==0, "Internal error in FTBaseGenerateRealFHTPlan: stack ptr!");
        }


        /*************************************************************************
        This subroutine executes FFT/FHT plan.

        If Plan is a:
        * complex FFT plan  -   sizeof(A)=2*N,
                                A contains interleaved real/imaginary values
        * real FFT plan     -   sizeof(A)=2*N,
                                A contains real values interleaved with zeros
        * real FHT plan     -   sizeof(A)=2*N,
                                A contains real values interleaved with zeros

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        public static void ftbaseexecuteplan(ref double[] a,
            int aoffset,
            int n,
            ref ftplan plan)
        {
            int stackptr = 0;

            stackptr = 0;
            ftbaseexecuteplanrec(ref a, aoffset, ref plan, 0, stackptr);
        }


        /*************************************************************************
        Recurrent subroutine for the FTBaseExecutePlan

        Parameters:
            A           FFT'ed array
            AOffset     offset of the FFT'ed part (distance is measured in doubles)

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        public static void ftbaseexecuteplanrec(ref double[] a,
            int aoffset,
            ref ftplan plan,
            int entryoffset,
            int stackptr)
        {
            int i = 0;
            int j = 0;
            int k = 0;
            int idx = 0;
            int n1 = 0;
            int n2 = 0;
            int n = 0;
            int m = 0;
            int offs = 0;
            int offs1 = 0;
            int offs2 = 0;
            int offsa = 0;
            int offsb = 0;
            int offsp = 0;
            double hk = 0;
            double hnk = 0;
            double x = 0;
            double y = 0;
            double bx = 0;
            double by = 0;
            double v = 0;
            double[] emptyarray = new double[0];
            double a0x = 0;
            double a0y = 0;
            double a1x = 0;
            double a1y = 0;
            double a2x = 0;
            double a2y = 0;
            double a3x = 0;
            double a3y = 0;
            double a4x = 0;
            double a4y = 0;
            double v0 = 0;
            double v1 = 0;
            double v2 = 0;
            double v3 = 0;
            double t1x = 0;
            double t1y = 0;
            double t2x = 0;
            double t2y = 0;
            double t3x = 0;
            double t3y = 0;
            double t4x = 0;
            double t4y = 0;
            double t5x = 0;
            double t5y = 0;
            double m1x = 0;
            double m1y = 0;
            double m2x = 0;
            double m2y = 0;
            double m3x = 0;
            double m3y = 0;
            double m4x = 0;
            double m4y = 0;
            double m5x = 0;
            double m5y = 0;
            double s1x = 0;
            double s1y = 0;
            double s2x = 0;
            double s2y = 0;
            double s3x = 0;
            double s3y = 0;
            double s4x = 0;
            double s4y = 0;
            double s5x = 0;
            double s5y = 0;
            double c1 = 0;
            double c2 = 0;
            double c3 = 0;
            double c4 = 0;
            double c5 = 0;
            double[] tmp = new double[0];
            int i_ = 0;
            int i1_ = 0;

            if( plan.plan[entryoffset+3]==fftemptyplan )
            {
                return;
            }
            if( plan.plan[entryoffset+3]==fftcooleytukeyplan )
            {
                
                //
                // Cooley-Tukey plan
                // * transposition
                // * row-wise FFT
                // * twiddle factors:
                //   - TwBase is a basis twiddle factor for I=1, J=1
                //   - TwRow is a twiddle factor for a second element in a row (J=1)
                //   - Tw is a twiddle factor for a current element
                // * transposition again
                // * row-wise FFT again
                //
                n1 = plan.plan[entryoffset+1];
                n2 = plan.plan[entryoffset+2];
                internalcomplexlintranspose(ref a, n1, n2, aoffset, ref plan.tmpbuf);
                for(i=0; i<=n2-1; i++)
                {
                    ftbaseexecuteplanrec(ref a, aoffset+i*n1*2, ref plan, plan.plan[entryoffset+5], stackptr);
                }
                ffttwcalc(ref a, aoffset, n1, n2);
                internalcomplexlintranspose(ref a, n2, n1, aoffset, ref plan.tmpbuf);
                for(i=0; i<=n1-1; i++)
                {
                    ftbaseexecuteplanrec(ref a, aoffset+i*n2*2, ref plan, plan.plan[entryoffset+6], stackptr);
                }
                internalcomplexlintranspose(ref a, n1, n2, aoffset, ref plan.tmpbuf);
                return;
            }
            if( plan.plan[entryoffset+3]==fftrealcooleytukeyplan )
            {
                
                //
                // Cooley-Tukey plan
                // * transposition
                // * row-wise FFT
                // * twiddle factors:
                //   - TwBase is a basis twiddle factor for I=1, J=1
                //   - TwRow is a twiddle factor for a second element in a row (J=1)
                //   - Tw is a twiddle factor for a current element
                // * transposition again
                // * row-wise FFT again
                //
                n1 = plan.plan[entryoffset+1];
                n2 = plan.plan[entryoffset+2];
                internalcomplexlintranspose(ref a, n2, n1, aoffset, ref plan.tmpbuf);
                for(i=0; i<=n1/2-1; i++)
                {
                    
                    //
                    // pack two adjacent smaller real FFT's together,
                    // make one complex FFT,
                    // unpack result
                    //
                    offs = aoffset+2*i*n2*2;
                    for(k=0; k<=n2-1; k++)
                    {
                        a[offs+2*k+1] = a[offs+2*n2+2*k+0];
                    }
                    ftbaseexecuteplanrec(ref a, offs, ref plan, plan.plan[entryoffset+6], stackptr);
                    plan.tmpbuf[0] = a[offs+0];
                    plan.tmpbuf[1] = 0;
                    plan.tmpbuf[2*n2+0] = a[offs+1];
                    plan.tmpbuf[2*n2+1] = 0;
                    for(k=1; k<=n2-1; k++)
                    {
                        offs1 = 2*k;
                        offs2 = 2*n2+2*k;
                        hk = a[offs+2*k+0];
                        hnk = a[offs+2*(n2-k)+0];
                        plan.tmpbuf[offs1+0] = +(0.5*(hk+hnk));
                        plan.tmpbuf[offs2+1] = -(0.5*(hk-hnk));
                        hk = a[offs+2*k+1];
                        hnk = a[offs+2*(n2-k)+1];
                        plan.tmpbuf[offs2+0] = +(0.5*(hk+hnk));
                        plan.tmpbuf[offs1+1] = +(0.5*(hk-hnk));
                    }
                    i1_ = (0) - (offs);
                    for(i_=offs; i_<=offs+2*n2*2-1;i_++)
                    {
                        a[i_] = plan.tmpbuf[i_+i1_];
                    }
                }
                if( n1%2!=0 )
                {
                    ftbaseexecuteplanrec(ref a, aoffset+(n1-1)*n2*2, ref plan, plan.plan[entryoffset+6], stackptr);
                }
                ffttwcalc(ref a, aoffset, n2, n1);
                internalcomplexlintranspose(ref a, n1, n2, aoffset, ref plan.tmpbuf);
                for(i=0; i<=n2-1; i++)
                {
                    ftbaseexecuteplanrec(ref a, aoffset+i*n1*2, ref plan, plan.plan[entryoffset+5], stackptr);
                }
                internalcomplexlintranspose(ref a, n2, n1, aoffset, ref plan.tmpbuf);
                return;
            }
            if( plan.plan[entryoffset+3]==fhtcooleytukeyplan )
            {
                
                //
                // Cooley-Tukey FHT plan:
                // * transpose                    \
                // * smaller FHT's                |
                // * pre-process                  |
                // * multiply by twiddle factors  | corresponds to multiplication by H1
                // * post-process                 |
                // * transpose again              /
                // * multiply by H2 (smaller FHT's)
                // * final transposition
                //
                // For more details see Vitezslav Vesely, "Fast algorithms
                // of Fourier and Hartley transform and their implementation in MATLAB",
                // page 31.
                //
                n1 = plan.plan[entryoffset+1];
                n2 = plan.plan[entryoffset+2];
                n = n1*n2;
                internalreallintranspose(ref a, n1, n2, aoffset, ref plan.tmpbuf);
                for(i=0; i<=n2-1; i++)
                {
                    ftbaseexecuteplanrec(ref a, aoffset+i*n1, ref plan, plan.plan[entryoffset+5], stackptr);
                }
                for(i=0; i<=n2-1; i++)
                {
                    for(j=0; j<=n1-1; j++)
                    {
                        offsa = aoffset+i*n1;
                        hk = a[offsa+j];
                        hnk = a[offsa+(n1-j)%n1];
                        offs = 2*(i*n1+j);
                        plan.tmpbuf[offs+0] = -(0.5*(hnk-hk));
                        plan.tmpbuf[offs+1] = +(0.5*(hk+hnk));
                    }
                }
                ffttwcalc(ref plan.tmpbuf, 0, n1, n2);
                for(j=0; j<=n1-1; j++)
                {
                    a[aoffset+j] = plan.tmpbuf[2*j+0]+plan.tmpbuf[2*j+1];
                }
                if( n2%2==0 )
                {
                    offs = 2*(n2/2)*n1;
                    offsa = aoffset+n2/2*n1;
                    for(j=0; j<=n1-1; j++)
                    {
                        a[offsa+j] = plan.tmpbuf[offs+2*j+0]+plan.tmpbuf[offs+2*j+1];
                    }
                }
                for(i=1; i<=(n2+1)/2-1; i++)
                {
                    offs = 2*i*n1;
                    offs2 = 2*(n2-i)*n1;
                    offsa = aoffset+i*n1;
                    for(j=0; j<=n1-1; j++)
                    {
                        a[offsa+j] = plan.tmpbuf[offs+2*j+1]+plan.tmpbuf[offs2+2*j+0];
                    }
                    offsa = aoffset+(n2-i)*n1;
                    for(j=0; j<=n1-1; j++)
                    {
                        a[offsa+j] = plan.tmpbuf[offs+2*j+0]+plan.tmpbuf[offs2+2*j+1];
                    }
                }
                internalreallintranspose(ref a, n2, n1, aoffset, ref plan.tmpbuf);
                for(i=0; i<=n1-1; i++)
                {
                    ftbaseexecuteplanrec(ref a, aoffset+i*n2, ref plan, plan.plan[entryoffset+6], stackptr);
                }
                internalreallintranspose(ref a, n1, n2, aoffset, ref plan.tmpbuf);
                return;
            }
            if( plan.plan[entryoffset+3]==fhtn2plan )
            {
                
                //
                // Cooley-Tukey FHT plan
                //
                n1 = plan.plan[entryoffset+1];
                n2 = plan.plan[entryoffset+2];
                n = n1*n2;
                reffht(ref a, n, aoffset);
                return;
            }
            if( plan.plan[entryoffset+3]==fftcodeletplan )
            {
                n1 = plan.plan[entryoffset+1];
                n2 = plan.plan[entryoffset+2];
                n = n1*n2;
                if( n==2 )
                {
                    a0x = a[aoffset+0];
                    a0y = a[aoffset+1];
                    a1x = a[aoffset+2];
                    a1y = a[aoffset+3];
                    v0 = a0x+a1x;
                    v1 = a0y+a1y;
                    v2 = a0x-a1x;
                    v3 = a0y-a1y;
                    a[aoffset+0] = v0;
                    a[aoffset+1] = v1;
                    a[aoffset+2] = v2;
                    a[aoffset+3] = v3;
                    return;
                }
                if( n==3 )
                {
                    offs = plan.plan[entryoffset+7];
                    c1 = plan.precomputed[offs+0];
                    c2 = plan.precomputed[offs+1];
                    a0x = a[aoffset+0];
                    a0y = a[aoffset+1];
                    a1x = a[aoffset+2];
                    a1y = a[aoffset+3];
                    a2x = a[aoffset+4];
                    a2y = a[aoffset+5];
                    t1x = a1x+a2x;
                    t1y = a1y+a2y;
                    a0x = a0x+t1x;
                    a0y = a0y+t1y;
                    m1x = c1*t1x;
                    m1y = c1*t1y;
                    m2x = c2*(a1y-a2y);
                    m2y = c2*(a2x-a1x);
                    s1x = a0x+m1x;
                    s1y = a0y+m1y;
                    a1x = s1x+m2x;
                    a1y = s1y+m2y;
                    a2x = s1x-m2x;
                    a2y = s1y-m2y;
                    a[aoffset+0] = a0x;
                    a[aoffset+1] = a0y;
                    a[aoffset+2] = a1x;
                    a[aoffset+3] = a1y;
                    a[aoffset+4] = a2x;
                    a[aoffset+5] = a2y;
                    return;
                }
                if( n==4 )
                {
                    a0x = a[aoffset+0];
                    a0y = a[aoffset+1];
                    a1x = a[aoffset+2];
                    a1y = a[aoffset+3];
                    a2x = a[aoffset+4];
                    a2y = a[aoffset+5];
                    a3x = a[aoffset+6];
                    a3y = a[aoffset+7];
                    t1x = a0x+a2x;
                    t1y = a0y+a2y;
                    t2x = a1x+a3x;
                    t2y = a1y+a3y;
                    m2x = a0x-a2x;
                    m2y = a0y-a2y;
                    m3x = a1y-a3y;
                    m3y = a3x-a1x;
                    a[aoffset+0] = t1x+t2x;
                    a[aoffset+1] = t1y+t2y;
                    a[aoffset+4] = t1x-t2x;
                    a[aoffset+5] = t1y-t2y;
                    a[aoffset+2] = m2x+m3x;
                    a[aoffset+3] = m2y+m3y;
                    a[aoffset+6] = m2x-m3x;
                    a[aoffset+7] = m2y-m3y;
                    return;
                }
                if( n==5 )
                {
                    offs = plan.plan[entryoffset+7];
                    c1 = plan.precomputed[offs+0];
                    c2 = plan.precomputed[offs+1];
                    c3 = plan.precomputed[offs+2];
                    c4 = plan.precomputed[offs+3];
                    c5 = plan.precomputed[offs+4];
                    t1x = a[aoffset+2]+a[aoffset+8];
                    t1y = a[aoffset+3]+a[aoffset+9];
                    t2x = a[aoffset+4]+a[aoffset+6];
                    t2y = a[aoffset+5]+a[aoffset+7];
                    t3x = a[aoffset+2]-a[aoffset+8];
                    t3y = a[aoffset+3]-a[aoffset+9];
                    t4x = a[aoffset+6]-a[aoffset+4];
                    t4y = a[aoffset+7]-a[aoffset+5];
                    t5x = t1x+t2x;
                    t5y = t1y+t2y;
                    a[aoffset+0] = a[aoffset+0]+t5x;
                    a[aoffset+1] = a[aoffset+1]+t5y;
                    m1x = c1*t5x;
                    m1y = c1*t5y;
                    m2x = c2*(t1x-t2x);
                    m2y = c2*(t1y-t2y);
                    m3x = -(c3*(t3y+t4y));
                    m3y = c3*(t3x+t4x);
                    m4x = -(c4*t4y);
                    m4y = c4*t4x;
                    m5x = -(c5*t3y);
                    m5y = c5*t3x;
                    s3x = m3x-m4x;
                    s3y = m3y-m4y;
                    s5x = m3x+m5x;
                    s5y = m3y+m5y;
                    s1x = a[aoffset+0]+m1x;
                    s1y = a[aoffset+1]+m1y;
                    s2x = s1x+m2x;
                    s2y = s1y+m2y;
                    s4x = s1x-m2x;
                    s4y = s1y-m2y;
                    a[aoffset+2] = s2x+s3x;
                    a[aoffset+3] = s2y+s3y;
                    a[aoffset+4] = s4x+s5x;
                    a[aoffset+5] = s4y+s5y;
                    a[aoffset+6] = s4x-s5x;
                    a[aoffset+7] = s4y-s5y;
                    a[aoffset+8] = s2x-s3x;
                    a[aoffset+9] = s2y-s3y;
                    return;
                }
            }
            if( plan.plan[entryoffset+3]==fhtcodeletplan )
            {
                n1 = plan.plan[entryoffset+1];
                n2 = plan.plan[entryoffset+2];
                n = n1*n2;
                if( n==2 )
                {
                    a0x = a[aoffset+0];
                    a1x = a[aoffset+1];
                    a[aoffset+0] = a0x+a1x;
                    a[aoffset+1] = a0x-a1x;
                    return;
                }
                if( n==3 )
                {
                    offs = plan.plan[entryoffset+7];
                    c1 = plan.precomputed[offs+0];
                    c2 = plan.precomputed[offs+1];
                    a0x = a[aoffset+0];
                    a1x = a[aoffset+1];
                    a2x = a[aoffset+2];
                    t1x = a1x+a2x;
                    a0x = a0x+t1x;
                    m1x = c1*t1x;
                    m2y = c2*(a2x-a1x);
                    s1x = a0x+m1x;
                    a[aoffset+0] = a0x;
                    a[aoffset+1] = s1x-m2y;
                    a[aoffset+2] = s1x+m2y;
                    return;
                }
                if( n==4 )
                {
                    a0x = a[aoffset+0];
                    a1x = a[aoffset+1];
                    a2x = a[aoffset+2];
                    a3x = a[aoffset+3];
                    t1x = a0x+a2x;
                    t2x = a1x+a3x;
                    m2x = a0x-a2x;
                    m3y = a3x-a1x;
                    a[aoffset+0] = t1x+t2x;
                    a[aoffset+1] = m2x-m3y;
                    a[aoffset+2] = t1x-t2x;
                    a[aoffset+3] = m2x+m3y;
                    return;
                }
                if( n==5 )
                {
                    offs = plan.plan[entryoffset+7];
                    c1 = plan.precomputed[offs+0];
                    c2 = plan.precomputed[offs+1];
                    c3 = plan.precomputed[offs+2];
                    c4 = plan.precomputed[offs+3];
                    c5 = plan.precomputed[offs+4];
                    t1x = a[aoffset+1]+a[aoffset+4];
                    t2x = a[aoffset+2]+a[aoffset+3];
                    t3x = a[aoffset+1]-a[aoffset+4];
                    t4x = a[aoffset+3]-a[aoffset+2];
                    t5x = t1x+t2x;
                    v0 = a[aoffset+0]+t5x;
                    a[aoffset+0] = v0;
                    m2x = c2*(t1x-t2x);
                    m3y = c3*(t3x+t4x);
                    s3y = m3y-c4*t4x;
                    s5y = m3y+c5*t3x;
                    s1x = v0+c1*t5x;
                    s2x = s1x+m2x;
                    s4x = s1x-m2x;
                    a[aoffset+1] = s2x-s3y;
                    a[aoffset+2] = s4x-s5y;
                    a[aoffset+3] = s4x+s5y;
                    a[aoffset+4] = s2x+s3y;
                    return;
                }
            }
            if( plan.plan[entryoffset+3]==fftbluesteinplan )
            {
                
                //
                // Bluestein plan:
                // 1. multiply by precomputed coefficients
                // 2. make convolution: forward FFT, multiplication by precomputed FFT
                //    and backward FFT. backward FFT is represented as
                //
                //        invfft(x) = fft(x')'/M
                //
                //    for performance reasons reduction of inverse FFT to
                //    forward FFT is merged with multiplication of FFT components
                //    and last stage of Bluestein's transformation.
                // 3. post-multiplication by Bluestein factors
                //
                n = plan.plan[entryoffset+1];
                m = plan.plan[entryoffset+4];
                offs = plan.plan[entryoffset+7];
                for(i=stackptr+2*n; i<=stackptr+2*m-1; i++)
                {
                    plan.stackbuf[i] = 0;
                }
                offsp = offs+2*m;
                offsa = aoffset;
                offsb = stackptr;
                for(i=0; i<=n-1; i++)
                {
                    bx = plan.precomputed[offsp+0];
                    by = plan.precomputed[offsp+1];
                    x = a[offsa+0];
                    y = a[offsa+1];
                    plan.stackbuf[offsb+0] = x*bx-y*-by;
                    plan.stackbuf[offsb+1] = x*-by+y*bx;
                    offsp = offsp+2;
                    offsa = offsa+2;
                    offsb = offsb+2;
                }
                ftbaseexecuteplanrec(ref plan.stackbuf, stackptr, ref plan, plan.plan[entryoffset+5], stackptr+2*2*m);
                offsb = stackptr;
                offsp = offs;
                for(i=0; i<=m-1; i++)
                {
                    x = plan.stackbuf[offsb+0];
                    y = plan.stackbuf[offsb+1];
                    bx = plan.precomputed[offsp+0];
                    by = plan.precomputed[offsp+1];
                    plan.stackbuf[offsb+0] = x*bx-y*by;
                    plan.stackbuf[offsb+1] = -(x*by+y*bx);
                    offsb = offsb+2;
                    offsp = offsp+2;
                }
                ftbaseexecuteplanrec(ref plan.stackbuf, stackptr, ref plan, plan.plan[entryoffset+5], stackptr+2*2*m);
                offsb = stackptr;
                offsp = offs+2*m;
                offsa = aoffset;
                for(i=0; i<=n-1; i++)
                {
                    x = +(plan.stackbuf[offsb+0]/m);
                    y = -(plan.stackbuf[offsb+1]/m);
                    bx = plan.precomputed[offsp+0];
                    by = plan.precomputed[offsp+1];
                    a[offsa+0] = x*bx-y*-by;
                    a[offsa+1] = x*-by+y*bx;
                    offsp = offsp+2;
                    offsa = offsa+2;
                    offsb = offsb+2;
                }
                return;
            }
        }


        /*************************************************************************
        Returns good factorization N=N1*N2.

        Usually N1<=N2 (but not always - small N's may be exception).
        if N1<>1 then N2<>1.

        Factorization is chosen depending on task type and codelets we have.

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        public static void ftbasefactorize(int n,
            int tasktype,
            ref int n1,
            ref int n2)
        {
            int j = 0;

            n1 = 0;
            n2 = 0;
            
            //
            // try to find good codelet
            //
            if( n1*n2!=n )
            {
                for(j=ftbasecodeletrecommended; j>=2; j--)
                {
                    if( n%j==0 )
                    {
                        n1 = j;
                        n2 = n/j;
                        break;
                    }
                }
            }
            
            //
            // try to factorize N
            //
            if( n1*n2!=n )
            {
                for(j=ftbasecodeletrecommended+1; j<=n-1; j++)
                {
                    if( n%j==0 )
                    {
                        n1 = j;
                        n2 = n/j;
                        break;
                    }
                }
            }
            
            //
            // looks like N is prime :(
            //
            if( n1*n2!=n )
            {
                n1 = 1;
                n2 = n;
            }
            
            //
            // normalize
            //
            if( n2==1 & n1!=1 )
            {
                n2 = n1;
                n1 = 1;
            }
        }


        /*************************************************************************
        Is number smooth?

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        public static bool ftbaseissmooth(int n)
        {
            bool result = new bool();
            int i = 0;

            for(i=2; i<=ftbasemaxsmoothfactor; i++)
            {
                while( n%i==0 )
                {
                    n = n/i;
                }
            }
            result = n==1;
            return result;
        }


        /*************************************************************************
        Returns smallest smooth (divisible only by 2, 3, 5) number that is greater
        than or equal to max(N,2)

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        public static int ftbasefindsmooth(int n)
        {
            int result = 0;
            int best = 0;

            best = 2;
            while( best<n )
            {
                best = 2*best;
            }
            ftbasefindsmoothrec(n, 1, 2, ref best);
            result = best;
            return result;
        }


        /*************************************************************************
        Returns  smallest  smooth  (divisible only by 2, 3, 5) even number that is
        greater than or equal to max(N,2)

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        public static int ftbasefindsmootheven(int n)
        {
            int result = 0;
            int best = 0;

            best = 2;
            while( best<n )
            {
                best = 2*best;
            }
            ftbasefindsmoothrec(n, 2, 2, ref best);
            result = best;
            return result;
        }


        /*************************************************************************
        Returns estimate of FLOP count for the FFT.

        It is only an estimate based on operations count for the PERFECT FFT
        and relative inefficiency of the algorithm actually used.

        N should be power of 2, estimates are badly wrong for non-power-of-2 N's.

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        public static double ftbasegetflopestimate(int n)
        {
            double result = 0;

            result = ftbaseinefficiencyfactor*(4*n*Math.Log(n)/Math.Log(2)-6*n+8);
            return result;
        }


        /*************************************************************************
        Recurrent subroutine for the FFTGeneratePlan:

        PARAMETERS:
            N                   plan size
            IsReal              whether input is real or not.
                                subroutine MUST NOT ignore this flag because real
                                inputs comes with non-initialized imaginary parts,
                                so ignoring this flag will result in corrupted output
            HalfOut             whether full output or only half of it from 0 to
                                floor(N/2) is needed. This flag may be ignored if
                                doing so will simplify calculations
            Plan                plan array
            PlanSize            size of used part (in integers)
            PrecomputedSize     size of precomputed array allocated yet
            PlanArraySize       plan array size (actual)
            TmpMemSize          temporary memory required size
            BluesteinMemSize    temporary memory required size

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        private static void ftbasegenerateplanrec(int n,
            int tasktype,
            ref ftplan plan,
            ref int plansize,
            ref int precomputedsize,
            ref int planarraysize,
            ref int tmpmemsize,
            ref int stackmemsize,
            int stackptr)
        {
            int j = 0;
            int k = 0;
            int m = 0;
            int n1 = 0;
            int n2 = 0;
            int esize = 0;
            int entryoffset = 0;

            
            //
            // prepare
            //
            if( plansize+ftbaseplanentrysize>planarraysize )
            {
                fftarrayresize(ref plan.plan, ref planarraysize, 8*planarraysize);
            }
            entryoffset = plansize;
            esize = ftbaseplanentrysize;
            plansize = plansize+esize;
            
            //
            // if N=1, generate empty plan and exit
            //
            if( n==1 )
            {
                plan.plan[entryoffset+0] = esize;
                plan.plan[entryoffset+1] = -1;
                plan.plan[entryoffset+2] = -1;
                plan.plan[entryoffset+3] = fftemptyplan;
                plan.plan[entryoffset+4] = -1;
                plan.plan[entryoffset+5] = -1;
                plan.plan[entryoffset+6] = -1;
                plan.plan[entryoffset+7] = -1;
                return;
            }
            
            //
            // generate plans
            //
            ftbasefactorize(n, tasktype, ref n1, ref n2);
            if( tasktype==ftbasecffttask | tasktype==ftbaserffttask )
            {
                
                //
                // complex FFT plans
                //
                if( n1!=1 )
                {
                    
                    //
                    // Cooley-Tukey plan (real or complex)
                    //
                    // Note that child plans are COMPLEX
                    // (whether plan itself is complex or not).
                    //
                    tmpmemsize = Math.Max(tmpmemsize, 2*n1*n2);
                    plan.plan[entryoffset+0] = esize;
                    plan.plan[entryoffset+1] = n1;
                    plan.plan[entryoffset+2] = n2;
                    if( tasktype==ftbasecffttask )
                    {
                        plan.plan[entryoffset+3] = fftcooleytukeyplan;
                    }
                    else
                    {
                        plan.plan[entryoffset+3] = fftrealcooleytukeyplan;
                    }
                    plan.plan[entryoffset+4] = 0;
                    plan.plan[entryoffset+5] = plansize;
                    ftbasegenerateplanrec(n1, ftbasecffttask, ref plan, ref plansize, ref precomputedsize, ref planarraysize, ref tmpmemsize, ref stackmemsize, stackptr);
                    plan.plan[entryoffset+6] = plansize;
                    ftbasegenerateplanrec(n2, ftbasecffttask, ref plan, ref plansize, ref precomputedsize, ref planarraysize, ref tmpmemsize, ref stackmemsize, stackptr);
                    plan.plan[entryoffset+7] = -1;
                    return;
                }
                else
                {
                    if( n==2 | n==3 | n==4 | n==5 )
                    {
                        
                        //
                        // hard-coded plan
                        //
                        plan.plan[entryoffset+0] = esize;
                        plan.plan[entryoffset+1] = n1;
                        plan.plan[entryoffset+2] = n2;
                        plan.plan[entryoffset+3] = fftcodeletplan;
                        plan.plan[entryoffset+4] = 0;
                        plan.plan[entryoffset+5] = -1;
                        plan.plan[entryoffset+6] = -1;
                        plan.plan[entryoffset+7] = precomputedsize;
                        if( n==3 )
                        {
                            precomputedsize = precomputedsize+2;
                        }
                        if( n==5 )
                        {
                            precomputedsize = precomputedsize+5;
                        }
                        return;
                    }
                    else
                    {
                        
                        //
                        // Bluestein's plan
                        //
                        // Select such M that M>=2*N-1, M is composite, and M's
                        // factors are 2, 3, 5
                        //
                        k = 2*n2-1;
                        m = ftbasefindsmooth(k);
                        tmpmemsize = Math.Max(tmpmemsize, 2*m);
                        plan.plan[entryoffset+0] = esize;
                        plan.plan[entryoffset+1] = n2;
                        plan.plan[entryoffset+2] = -1;
                        plan.plan[entryoffset+3] = fftbluesteinplan;
                        plan.plan[entryoffset+4] = m;
                        plan.plan[entryoffset+5] = plansize;
                        stackptr = stackptr+2*2*m;
                        stackmemsize = Math.Max(stackmemsize, stackptr);
                        ftbasegenerateplanrec(m, ftbasecffttask, ref plan, ref plansize, ref precomputedsize, ref planarraysize, ref tmpmemsize, ref stackmemsize, stackptr);
                        stackptr = stackptr-2*2*m;
                        plan.plan[entryoffset+6] = -1;
                        plan.plan[entryoffset+7] = precomputedsize;
                        precomputedsize = precomputedsize+2*m+2*n;
                        return;
                    }
                }
            }
            if( tasktype==ftbaserfhttask )
            {
                
                //
                // real FHT plans
                //
                if( n1!=1 )
                {
                    
                    //
                    // Cooley-Tukey plan
                    //
                    //
                    tmpmemsize = Math.Max(tmpmemsize, 2*n1*n2);
                    plan.plan[entryoffset+0] = esize;
                    plan.plan[entryoffset+1] = n1;
                    plan.plan[entryoffset+2] = n2;
                    plan.plan[entryoffset+3] = fhtcooleytukeyplan;
                    plan.plan[entryoffset+4] = 0;
                    plan.plan[entryoffset+5] = plansize;
                    ftbasegenerateplanrec(n1, tasktype, ref plan, ref plansize, ref precomputedsize, ref planarraysize, ref tmpmemsize, ref stackmemsize, stackptr);
                    plan.plan[entryoffset+6] = plansize;
                    ftbasegenerateplanrec(n2, tasktype, ref plan, ref plansize, ref precomputedsize, ref planarraysize, ref tmpmemsize, ref stackmemsize, stackptr);
                    plan.plan[entryoffset+7] = -1;
                    return;
                }
                else
                {
                    
                    //
                    // N2 plan
                    //
                    plan.plan[entryoffset+0] = esize;
                    plan.plan[entryoffset+1] = n1;
                    plan.plan[entryoffset+2] = n2;
                    plan.plan[entryoffset+3] = fhtn2plan;
                    plan.plan[entryoffset+4] = 0;
                    plan.plan[entryoffset+5] = -1;
                    plan.plan[entryoffset+6] = -1;
                    plan.plan[entryoffset+7] = -1;
                    if( n==2 | n==3 | n==4 | n==5 )
                    {
                        
                        //
                        // hard-coded plan
                        //
                        plan.plan[entryoffset+0] = esize;
                        plan.plan[entryoffset+1] = n1;
                        plan.plan[entryoffset+2] = n2;
                        plan.plan[entryoffset+3] = fhtcodeletplan;
                        plan.plan[entryoffset+4] = 0;
                        plan.plan[entryoffset+5] = -1;
                        plan.plan[entryoffset+6] = -1;
                        plan.plan[entryoffset+7] = precomputedsize;
                        if( n==3 )
                        {
                            precomputedsize = precomputedsize+2;
                        }
                        if( n==5 )
                        {
                            precomputedsize = precomputedsize+5;
                        }
                        return;
                    }
                    return;
                }
            }
        }


        /*************************************************************************
        Recurrent subroutine for precomputing FFT plans

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        private static void ftbaseprecomputeplanrec(ref ftplan plan,
            int entryoffset,
            int stackptr)
        {
            int i = 0;
            int j = 0;
            int idx = 0;
            int n1 = 0;
            int n2 = 0;
            int n = 0;
            int m = 0;
            int offs = 0;
            double v = 0;
            double[] emptyarray = new double[0];
            double bx = 0;
            double by = 0;

            if( plan.plan[entryoffset+3]==fftcooleytukeyplan | plan.plan[entryoffset+3]==fftrealcooleytukeyplan | plan.plan[entryoffset+3]==fhtcooleytukeyplan )
            {
                ftbaseprecomputeplanrec(ref plan, plan.plan[entryoffset+5], stackptr);
                ftbaseprecomputeplanrec(ref plan, plan.plan[entryoffset+6], stackptr);
                return;
            }
            if( plan.plan[entryoffset+3]==fftcodeletplan | plan.plan[entryoffset+3]==fhtcodeletplan )
            {
                n1 = plan.plan[entryoffset+1];
                n2 = plan.plan[entryoffset+2];
                n = n1*n2;
                if( n==3 )
                {
                    offs = plan.plan[entryoffset+7];
                    plan.precomputed[offs+0] = Math.Cos(2*Math.PI/3)-1;
                    plan.precomputed[offs+1] = Math.Sin(2*Math.PI/3);
                    return;
                }
                if( n==5 )
                {
                    offs = plan.plan[entryoffset+7];
                    v = 2*Math.PI/5;
                    plan.precomputed[offs+0] = (Math.Cos(v)+Math.Cos(2*v))/2-1;
                    plan.precomputed[offs+1] = (Math.Cos(v)-Math.Cos(2*v))/2;
                    plan.precomputed[offs+2] = -Math.Sin(v);
                    plan.precomputed[offs+3] = -(Math.Sin(v)+Math.Sin(2*v));
                    plan.precomputed[offs+4] = Math.Sin(v)-Math.Sin(2*v);
                    return;
                }
            }
            if( plan.plan[entryoffset+3]==fftbluesteinplan )
            {
                ftbaseprecomputeplanrec(ref plan, plan.plan[entryoffset+5], stackptr);
                n = plan.plan[entryoffset+1];
                m = plan.plan[entryoffset+4];
                offs = plan.plan[entryoffset+7];
                for(i=0; i<=2*m-1; i++)
                {
                    plan.precomputed[offs+i] = 0;
                }
                for(i=0; i<=n-1; i++)
                {
                    bx = Math.Cos(Math.PI*AP.Math.Sqr(i)/n);
                    by = Math.Sin(Math.PI*AP.Math.Sqr(i)/n);
                    plan.precomputed[offs+2*i+0] = bx;
                    plan.precomputed[offs+2*i+1] = by;
                    plan.precomputed[offs+2*m+2*i+0] = bx;
                    plan.precomputed[offs+2*m+2*i+1] = by;
                    if( i>0 )
                    {
                        plan.precomputed[offs+2*(m-i)+0] = bx;
                        plan.precomputed[offs+2*(m-i)+1] = by;
                    }
                }
                ftbaseexecuteplanrec(ref plan.precomputed, offs, ref plan, plan.plan[entryoffset+5], stackptr);
                return;
            }
        }


        /*************************************************************************
        Twiddle factors calculation

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        private static void ffttwcalc(ref double[] a,
            int aoffset,
            int n1,
            int n2)
        {
            int i = 0;
            int j = 0;
            int n = 0;
            int idx = 0;
            int offs = 0;
            double x = 0;
            double y = 0;
            double twxm1 = 0;
            double twy = 0;
            double twbasexm1 = 0;
            double twbasey = 0;
            double twrowxm1 = 0;
            double twrowy = 0;
            double tmpx = 0;
            double tmpy = 0;
            double v = 0;

            n = n1*n2;
            v = -(2*Math.PI/n);
            twbasexm1 = -(2*AP.Math.Sqr(Math.Sin(0.5*v)));
            twbasey = Math.Sin(v);
            twrowxm1 = 0;
            twrowy = 0;
            for(i=0; i<=n2-1; i++)
            {
                twxm1 = 0;
                twy = 0;
                for(j=0; j<=n1-1; j++)
                {
                    idx = i*n1+j;
                    offs = aoffset+2*idx;
                    x = a[offs+0];
                    y = a[offs+1];
                    tmpx = x*twxm1-y*twy;
                    tmpy = x*twy+y*twxm1;
                    a[offs+0] = x+tmpx;
                    a[offs+1] = y+tmpy;
                    
                    //
                    // update Tw: Tw(new) = Tw(old)*TwRow
                    //
                    if( j<n1-1 )
                    {
                        if( j%ftbaseupdatetw==0 )
                        {
                            v = -(2*Math.PI*i*(j+1)/n);
                            twxm1 = -(2*AP.Math.Sqr(Math.Sin(0.5*v)));
                            twy = Math.Sin(v);
                        }
                        else
                        {
                            tmpx = twrowxm1+twxm1*twrowxm1-twy*twrowy;
                            tmpy = twrowy+twxm1*twrowy+twy*twrowxm1;
                            twxm1 = twxm1+tmpx;
                            twy = twy+tmpy;
                        }
                    }
                }
                
                //
                // update TwRow: TwRow(new) = TwRow(old)*TwBase
                //
                if( i<n2-1 )
                {
                    if( j%ftbaseupdatetw==0 )
                    {
                        v = -(2*Math.PI*(i+1)/n);
                        twrowxm1 = -(2*AP.Math.Sqr(Math.Sin(0.5*v)));
                        twrowy = Math.Sin(v);
                    }
                    else
                    {
                        tmpx = twbasexm1+twrowxm1*twbasexm1-twrowy*twbasey;
                        tmpy = twbasey+twrowxm1*twbasey+twrowy*twbasexm1;
                        twrowxm1 = twrowxm1+tmpx;
                        twrowy = twrowy+tmpy;
                    }
                }
            }
        }


        /*************************************************************************
        Linear transpose: transpose complex matrix stored in 1-dimensional array

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        private static void internalcomplexlintranspose(ref double[] a,
            int m,
            int n,
            int astart,
            ref double[] buf)
        {
            int i_ = 0;
            int i1_ = 0;

            ffticltrec(ref a, astart, n, ref buf, 0, m, m, n);
            i1_ = (0) - (astart);
            for(i_=astart; i_<=astart+2*m*n-1;i_++)
            {
                a[i_] = buf[i_+i1_];
            }
        }


        /*************************************************************************
        Linear transpose: transpose real matrix stored in 1-dimensional array

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        private static void internalreallintranspose(ref double[] a,
            int m,
            int n,
            int astart,
            ref double[] buf)
        {
            int i_ = 0;
            int i1_ = 0;

            fftirltrec(ref a, astart, n, ref buf, 0, m, m, n);
            i1_ = (0) - (astart);
            for(i_=astart; i_<=astart+m*n-1;i_++)
            {
                a[i_] = buf[i_+i1_];
            }
        }


        /*************************************************************************
        Recurrent subroutine for a InternalComplexLinTranspose

        Write A^T to B, where:
        * A is m*n complex matrix stored in array A as pairs of real/image values,
          beginning from AStart position, with AStride stride
        * B is n*m complex matrix stored in array B as pairs of real/image values,
          beginning from BStart position, with BStride stride
        stride is measured in complex numbers, i.e. in real/image pairs.

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        private static void ffticltrec(ref double[] a,
            int astart,
            int astride,
            ref double[] b,
            int bstart,
            int bstride,
            int m,
            int n)
        {
            int i = 0;
            int j = 0;
            int idx1 = 0;
            int idx2 = 0;
            int m2 = 0;
            int m1 = 0;
            int n1 = 0;

            if( m==0 | n==0 )
            {
                return;
            }
            if( Math.Max(m, n)<=8 )
            {
                m2 = 2*bstride;
                for(i=0; i<=m-1; i++)
                {
                    idx1 = bstart+2*i;
                    idx2 = astart+2*i*astride;
                    for(j=0; j<=n-1; j++)
                    {
                        b[idx1+0] = a[idx2+0];
                        b[idx1+1] = a[idx2+1];
                        idx1 = idx1+m2;
                        idx2 = idx2+2;
                    }
                }
                return;
            }
            if( n>m )
            {
                
                //
                // New partition:
                //
                // "A^T -> B" becomes "(A1 A2)^T -> ( B1 )
                //                                  ( B2 )
                //
                n1 = n/2;
                if( n-n1>=8 & n1%8!=0 )
                {
                    n1 = n1+(8-n1%8);
                }
                System.Diagnostics.Debug.Assert(n-n1>0);
                ffticltrec(ref a, astart, astride, ref b, bstart, bstride, m, n1);
                ffticltrec(ref a, astart+2*n1, astride, ref b, bstart+2*n1*bstride, bstride, m, n-n1);
            }
            else
            {
                
                //
                // New partition:
                //
                // "A^T -> B" becomes "( A1 )^T -> ( B1 B2 )
                //                     ( A2 )
                //
                m1 = m/2;
                if( m-m1>=8 & m1%8!=0 )
                {
                    m1 = m1+(8-m1%8);
                }
                System.Diagnostics.Debug.Assert(m-m1>0);
                ffticltrec(ref a, astart, astride, ref b, bstart, bstride, m1, n);
                ffticltrec(ref a, astart+2*m1*astride, astride, ref b, bstart+2*m1, bstride, m-m1, n);
            }
        }


        /*************************************************************************
        Recurrent subroutine for a InternalRealLinTranspose


          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        private static void fftirltrec(ref double[] a,
            int astart,
            int astride,
            ref double[] b,
            int bstart,
            int bstride,
            int m,
            int n)
        {
            int i = 0;
            int j = 0;
            int idx1 = 0;
            int idx2 = 0;
            int m1 = 0;
            int n1 = 0;

            if( m==0 | n==0 )
            {
                return;
            }
            if( Math.Max(m, n)<=8 )
            {
                for(i=0; i<=m-1; i++)
                {
                    idx1 = bstart+i;
                    idx2 = astart+i*astride;
                    for(j=0; j<=n-1; j++)
                    {
                        b[idx1] = a[idx2];
                        idx1 = idx1+bstride;
                        idx2 = idx2+1;
                    }
                }
                return;
            }
            if( n>m )
            {
                
                //
                // New partition:
                //
                // "A^T -> B" becomes "(A1 A2)^T -> ( B1 )
                //                                  ( B2 )
                //
                n1 = n/2;
                if( n-n1>=8 & n1%8!=0 )
                {
                    n1 = n1+(8-n1%8);
                }
                System.Diagnostics.Debug.Assert(n-n1>0);
                fftirltrec(ref a, astart, astride, ref b, bstart, bstride, m, n1);
                fftirltrec(ref a, astart+n1, astride, ref b, bstart+n1*bstride, bstride, m, n-n1);
            }
            else
            {
                
                //
                // New partition:
                //
                // "A^T -> B" becomes "( A1 )^T -> ( B1 B2 )
                //                     ( A2 )
                //
                m1 = m/2;
                if( m-m1>=8 & m1%8!=0 )
                {
                    m1 = m1+(8-m1%8);
                }
                System.Diagnostics.Debug.Assert(m-m1>0);
                fftirltrec(ref a, astart, astride, ref b, bstart, bstride, m1, n);
                fftirltrec(ref a, astart+m1*astride, astride, ref b, bstart+m1, bstride, m-m1, n);
            }
        }


        /*************************************************************************
        recurrent subroutine for FFTFindSmoothRec

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        private static void ftbasefindsmoothrec(int n,
            int seed,
            int leastfactor,
            ref int best)
        {
            System.Diagnostics.Debug.Assert(ftbasemaxsmoothfactor<=5, "FTBaseFindSmoothRec: internal error!");
            if( seed>=n )
            {
                best = Math.Min(best, seed);
                return;
            }
            if( leastfactor<=2 )
            {
                ftbasefindsmoothrec(n, seed*2, 2, ref best);
            }
            if( leastfactor<=3 )
            {
                ftbasefindsmoothrec(n, seed*3, 3, ref best);
            }
            if( leastfactor<=5 )
            {
                ftbasefindsmoothrec(n, seed*5, 5, ref best);
            }
        }


        /*************************************************************************
        Internal subroutine: array resize

          -- ALGLIB --
             Copyright 01.05.2009 by Bochkanov Sergey
        *************************************************************************/
        private static void fftarrayresize(ref int[] a,
            ref int asize,
            int newasize)
        {
            int[] tmp = new int[0];
            int i = 0;

            tmp = new int[asize];
            for(i=0; i<=asize-1; i++)
            {
                tmp[i] = a[i];
            }
            a = new int[newasize];
            for(i=0; i<=asize-1; i++)
            {
                a[i] = tmp[i];
            }
            asize = newasize;
        }


        /*************************************************************************
        Reference FHT stub
        *************************************************************************/
        private static void reffht(ref double[] a,
            int n,
            int offs)
        {
            double[] buf = new double[0];
            int i = 0;
            int j = 0;
            double v = 0;

            System.Diagnostics.Debug.Assert(n>0, "RefFHTR1D: incorrect N!");
            buf = new double[n];
            for(i=0; i<=n-1; i++)
            {
                v = 0;
                for(j=0; j<=n-1; j++)
                {
                    v = v+a[offs+j]*(Math.Cos(2*Math.PI*i*j/n)+Math.Sin(2*Math.PI*i*j/n));
                }
                buf[i] = v;
            }
            for(i=0; i<=n-1; i++)
            {
                a[offs+i] = buf[i];
            }
        }
    }
}