File: acb_dft.h

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/*
    Copyright (C) 2016 Pascal Molin

    This file is part of FLINT.

    FLINT is free software: you can redistribute it and/or modify it under
    the terms of the GNU Lesser General Public License (LGPL) as published
    by the Free Software Foundation; either version 3 of the License, or
    (at your option) any later version.  See <https://www.gnu.org/licenses/>.
*/

#ifndef ACB_DFT_H
#define ACB_DFT_H

#include "limb_types.h"
#include "acb.h"

#ifdef __cplusplus
extern "C" {
#endif

void _acb_dft_naive(acb_ptr w, acb_srcptr v, slong dv, acb_srcptr z, slong dz, slong len, slong prec);
void acb_dft_naive(acb_ptr w, acb_srcptr v, slong len, slong prec);
void acb_dft_crt(acb_ptr w, acb_srcptr v, slong len, slong prec);
void acb_dft_cyc(acb_ptr w, acb_srcptr v, slong len, slong prec);
void acb_dft_inverse_cyc(acb_ptr w, acb_srcptr v, slong len, slong prec);
void acb_dft_rad2_inplace(acb_ptr v, int e, slong prec);
void acb_dft_rad2(acb_ptr w, acb_srcptr v, int e, slong prec);
void acb_dft_bluestein(acb_ptr w, acb_srcptr v, slong len, slong prec);
void acb_dft_prod(acb_ptr w, acb_srcptr v, slong * cyc, slong num, slong prec);

void acb_dft_rad2_inplace_threaded(acb_ptr v, int e, slong prec);

void acb_dft_convol_naive(acb_ptr w, acb_srcptr f, acb_srcptr g, slong len, slong prec);
void acb_dft_convol_dft(acb_ptr w, acb_srcptr f, acb_srcptr g, slong len, slong prec);
void acb_dft_convol_rad2(acb_ptr w, acb_srcptr f, acb_srcptr g, slong len, slong prec);
void acb_dft_convol_mullow(acb_ptr w, acb_srcptr f, acb_srcptr g, slong len, slong prec);
void acb_dft_convol(acb_ptr w, acb_srcptr f, acb_srcptr g, slong len, slong prec);

#define CRT_MAX 15
typedef struct
{
    int num;
    nmod_t n;
    slong m[CRT_MAX];
    ulong M[CRT_MAX];
    ulong vM[CRT_MAX];
}
crt_struct;

typedef crt_struct crt_t[1];

void crt_init(crt_t c, ulong n);

void crt_decomp(acb_ptr y, acb_srcptr x, slong dx, const crt_t c, ulong len);
void crt_recomp(acb_ptr y, acb_srcptr x, const crt_t c, ulong len);

typedef struct acb_dft_step_struct acb_dft_step_struct;
typedef acb_dft_step_struct * acb_dft_step_ptr;

typedef struct
{
    slong n;
    acb_ptr z;
    int zclear;
    slong num;
    acb_dft_step_ptr cyc;
}
acb_dft_cyc_struct;

typedef acb_dft_cyc_struct acb_dft_cyc_t[1];

typedef struct
{
    int e;
    slong n; /* = 1 << e */
    slong dv;
    slong nz; /* = n but could be bigger */
    acb_ptr z;
}
acb_dft_rad2_struct;

typedef acb_dft_rad2_struct acb_dft_rad2_t[1];

typedef struct
{
    slong n;
    slong dv;
    acb_ptr z; /* z[k] = e(k^2/2n) */
    acb_ptr g; /* g[k] = dft( z ) */
    acb_dft_rad2_t rad2;
}
acb_dft_bluestein_struct;

typedef acb_dft_bluestein_struct acb_dft_bluestein_t[1];

typedef struct
{
    slong n;
    slong num;
    acb_dft_step_ptr cyc;
}
acb_dft_prod_struct;

typedef acb_dft_prod_struct acb_dft_prod_t[1];

typedef struct
{
    slong n;
    crt_t c;
    slong dv;
    /* then a product */
    acb_dft_step_ptr cyc;
}
acb_dft_crt_struct;

typedef acb_dft_crt_struct acb_dft_crt_t[1];

typedef struct
{
    slong n;
    slong dv;
    int zclear;
    acb_ptr z;
    slong dz;
}
acb_dft_naive_struct;

typedef acb_dft_naive_struct acb_dft_naive_t[1];

typedef struct
{
    slong n;
    int type;
    union
    {
        acb_dft_rad2_t rad2;
        acb_dft_cyc_t cyc;
        acb_dft_prod_t prod;
        acb_dft_crt_t crt;
        acb_dft_naive_t naive;
        acb_dft_bluestein_t bluestein;
    } t;
}
acb_dft_pre_struct;

typedef acb_dft_pre_struct acb_dft_pre_t[1];

/* covers both product and cyclic case */
struct
acb_dft_step_struct
{
    /* [G:H] */
    slong m;
    /* card H */
    slong M;
    slong dv; /* = M for prod, also = M if cyc is reordered */
    /* pointer on some roots of unity, if needed */
    acb_srcptr z;
    /* index of mM in z */
    slong dz;
    /* dft to call on H */
    acb_dft_pre_t pre;
    /* dft to call on G/H ? */
};

/*typedef acb_dft_pre_struct acb_dft_pre_t[1];*/

#define DFT_VERB 0

enum
{
    DFT_NAIVE, DFT_CYC, DFT_PROD, DFT_CRT , DFT_RAD2 , DFT_CONV
};

void acb_dft_step(acb_ptr w, acb_srcptr v, acb_dft_step_ptr cyc, slong num, slong prec);

void acb_dft_precomp(acb_ptr w, acb_srcptr v, const acb_dft_pre_t pre, slong prec);
void acb_dft_inverse_precomp(acb_ptr w, acb_srcptr v, const acb_dft_pre_t pre, slong prec);
void acb_dft_naive_precomp(acb_ptr w, acb_srcptr v, const acb_dft_naive_t pol, slong prec);
void acb_dft_cyc_precomp(acb_ptr w, acb_srcptr v, const acb_dft_cyc_t cyc, slong prec);

void acb_dft_rad2_precomp_inplace(acb_ptr v, const acb_dft_rad2_t rad2, slong prec);
void acb_dft_rad2_precomp(acb_ptr w, acb_srcptr v, const acb_dft_rad2_t rad2, slong prec);
void acb_dft_crt_precomp(acb_ptr w, acb_srcptr v, const acb_dft_crt_t crt, slong prec);
void acb_dft_prod_precomp(acb_ptr w, acb_srcptr v, const acb_dft_prod_t prod, slong prec);
void acb_dft_bluestein_precomp(acb_ptr w, acb_srcptr v, const acb_dft_bluestein_t t, slong prec);

void acb_dft_rad2_precomp_inplace_threaded(acb_ptr v, const acb_dft_rad2_t rad2, slong prec);

void acb_dft_inverse_rad2_precomp_inplace(acb_ptr v, const acb_dft_rad2_t rad2, slong prec);
void acb_dft_inverse_rad2_precomp(acb_ptr w, acb_srcptr v, const acb_dft_rad2_t rad2, slong prec);
void acb_dft_convol_rad2_precomp(acb_ptr w, acb_srcptr f, acb_srcptr g, slong len, const acb_dft_rad2_t, slong prec);

void _acb_dft_precomp_init(acb_dft_pre_t pre, slong dv, acb_ptr z, slong dz, slong len, slong prec);
void acb_dft_precomp_init(acb_dft_pre_t pre, slong len, slong prec);
void acb_dft_precomp_clear(acb_dft_pre_t pre);

void acb_dft(acb_ptr w, acb_srcptr v, slong len, slong prec);
void acb_dft_inverse(acb_ptr w, acb_srcptr v, slong len, slong prec);

acb_dft_step_ptr _acb_dft_steps_prod(slong * m, slong num, slong prec);

FLINT_FORCE_INLINE void
acb_dft_prod_init(acb_dft_prod_t t, slong * cyc, slong num, slong prec)
{
    t->num = num;
    t->cyc = _acb_dft_steps_prod(cyc, num, prec);
}

void acb_dft_prod_clear(acb_dft_prod_t t);

void _acb_dft_cyc_init_z_fac(acb_dft_cyc_t t, n_factor_t fac, slong dv, acb_ptr z, slong dz, slong len, slong prec);
void _acb_dft_cyc_init(acb_dft_cyc_t t, slong dv, slong len, slong prec);

FLINT_FORCE_INLINE void
acb_dft_cyc_init(acb_dft_cyc_t t, slong len, slong prec)
{
    _acb_dft_cyc_init(t, 1, len, prec);
}

void acb_dft_cyc_clear(acb_dft_cyc_t t);

void _acb_dft_naive_init(acb_dft_naive_t pol, slong dv, acb_ptr z, slong dz, slong len, slong prec);

FLINT_FORCE_INLINE void
acb_dft_naive_init(acb_dft_naive_t pol, slong len, slong prec)
{
    _acb_dft_naive_init(pol, 1, NULL, 0, len, prec);
}

FLINT_FORCE_INLINE void
acb_dft_naive_clear(acb_dft_naive_t pol)
{
    if (pol->zclear)
        _acb_vec_clear(pol->z, pol->n);
}

void _acb_dft_rad2_init(acb_dft_rad2_t t, slong dv, int e, slong prec);

FLINT_FORCE_INLINE void
acb_dft_rad2_init(acb_dft_rad2_t t, int e, slong prec)
{
    _acb_dft_rad2_init(t, 1, e, prec);
}

FLINT_FORCE_INLINE void
acb_dft_rad2_clear(acb_dft_rad2_t t)
{
    _acb_vec_clear(t->z, t->nz);
}

void _acb_dft_bluestein_init(acb_dft_bluestein_t t, slong dv, slong n, slong prec);

FLINT_FORCE_INLINE void
acb_dft_bluestein_init(acb_dft_bluestein_t t, slong n, slong prec)
{
    _acb_dft_bluestein_init(t, 1, n, prec);
}

FLINT_FORCE_INLINE void
acb_dft_bluestein_clear(acb_dft_bluestein_t t)
{
    if (t->n != 0)
    {
        _acb_vec_clear(t->z, t->n);
        _acb_vec_clear(t->g, t->rad2->n);
        acb_dft_rad2_clear(t->rad2);
    }
}

void _acb_dft_crt_init(acb_dft_crt_t crt, slong dv, slong len, slong prec);
void acb_dft_crt_init(acb_dft_crt_t crt, slong len, slong prec);
void acb_dft_crt_clear(acb_dft_crt_t crt);

/* utils, could be moved elsewhere */

FLINT_FORCE_INLINE void
acb_swap_ri(acb_t x)
{
    arb_swap(acb_realref(x), acb_imagref(x));
}

FLINT_FORCE_INLINE void
acb_vec_swap_ri(acb_ptr v, slong len)
{
    slong k;
    for (k = 0; k < len; k++)
        acb_swap_ri(v + k);
}

FLINT_FORCE_INLINE void
_acb_vec_kronecker_mul(acb_ptr z, acb_srcptr x, acb_srcptr y, slong len, slong prec)
{
    slong k;
    for (k = 0; k < len; k++)
        acb_mul(z + k, x + k, y + k, prec);
}

FLINT_FORCE_INLINE void
_acb_vec_kronecker_mul_step(acb_ptr z, acb_srcptr x, acb_srcptr y, slong step, slong len, slong prec)
{
    slong k;
    for (k = 0; k < len; k++)
    {
        acb_mul(z + k, x + k, y + k * step, prec);
    }
}

#ifdef __cplusplus
}
#endif

#endif