flint-sys 0.9.0

Bindings to the FLINT C library
Documentation 
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/*
    Copyright (C) 2010, 2011 Sebastian Pancratz

    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/>.
*/

#include "fmpq_poly.h"

#include "fmpz_poly_q.h"

void fmpz_poly_q_add_in_place(fmpz_poly_q_t rop, const fmpz_poly_q_t op)
{
    fmpz_poly_t d, poly, r2, s2;

    if (rop == op)
    {
        fmpz_poly_q_scalar_mul_si(rop, rop, 2);
        return;
    }

    if (fmpz_poly_q_is_zero(rop))
    {
        fmpz_poly_q_set(rop, op);
        return;
    }
    if (fmpz_poly_q_is_zero(op))
    {
        return;
    }

    /* Polynomials? */
    if (fmpz_poly_length(rop->den) == 1 && fmpz_poly_length(op->den) == 1)
    {
        const slong len1 = fmpz_poly_length(rop->num);
        const slong len2 = fmpz_poly_length(op->num);

        fmpz_poly_fit_length(rop->num, FLINT_MAX(len1, len2));
        _fmpq_poly_add(rop->num->coeffs, rop->den->coeffs,
                       rop->num->coeffs, rop->den->coeffs, len1,
                       op->num->coeffs, op->den->coeffs, len2);
        _fmpz_poly_set_length(rop->num, FLINT_MAX(len1, len2));
        _fmpz_poly_set_length(rop->den, 1);
        _fmpz_poly_normalise(rop->num);
        return;
    }

    /* Denominators equal to one? */
    if (fmpz_poly_is_one(rop->den))
    {
        fmpz_poly_mul(rop->num, rop->num, op->den);
        fmpz_poly_add(rop->num, rop->num, op->num);
        fmpz_poly_set(rop->den, op->den);
        return;
    }
    if (fmpz_poly_is_one(op->den))
    {
        fmpz_poly_init(poly);
        fmpz_poly_mul(poly, rop->den, op->num);
        fmpz_poly_add(rop->num, rop->num, poly);
        fmpz_poly_clear(poly);
        return;
    }

    /* Henrici's algorithm for summation in quotient fields */
    fmpz_poly_init(d);
    fmpz_poly_gcd(d, rop->den, op->den);

    if (fmpz_poly_is_one(d))
    {
        fmpz_poly_mul(rop->num, rop->num, op->den);
        fmpz_poly_mul(d, rop->den, op->num);  /* Using d as temp */
        fmpz_poly_add(rop->num, rop->num, d);
        fmpz_poly_mul(rop->den, rop->den, op->den);
    }
    else
    {
        fmpz_poly_init(r2);
        fmpz_poly_init(s2);

        fmpz_poly_divexact(r2, rop->den, d);
        fmpz_poly_divexact(s2, op->den, d);

        fmpz_poly_mul(rop->num, rop->num, s2);
        fmpz_poly_mul(s2, op->num, r2);  /* Using s2 as temp */
        fmpz_poly_add(rop->num, rop->num, s2);

        if (fmpz_poly_is_zero(rop->num))
        {
            fmpz_poly_zero(rop->den);
            fmpz_poly_set_coeff_si(rop->den, 0, 1);
        }
        else
        {
            fmpz_poly_mul(rop->den, r2, op->den);

            fmpz_poly_gcd(r2, rop->num, d);  /* Using r2 as temp */

            if (!fmpz_poly_is_one(r2))
            {
                fmpz_poly_divexact(rop->num, rop->num, r2);
                fmpz_poly_divexact(rop->den, rop->den, r2);
            }
        }
        fmpz_poly_clear(r2);
        fmpz_poly_clear(s2);
    }
    fmpz_poly_clear(d);
}

void
fmpz_poly_q_add(fmpz_poly_q_t rop,
                const fmpz_poly_q_t op1, const fmpz_poly_q_t op2)
{
    fmpz_poly_t d, r2, s2;

    if (fmpz_poly_q_is_zero(op1))
    {
        fmpz_poly_q_set(rop, op2);
        return;
    }
    if (fmpz_poly_q_is_zero(op2))
    {
        fmpz_poly_q_set(rop, op1);
        return;
    }

    if (op1 == op2)
    {
        fmpz_poly_q_scalar_mul_si(rop, op1, 2);
        return;
    }
    if (rop == op1)
    {
        fmpz_poly_q_add_in_place(rop, op2);
        return;
    }
    if (rop == op2)
    {
        fmpz_poly_q_add_in_place(rop, op1);
        return;
    }

    /*
        From here on, we may assume that rop, op1 and op2 all refer to
        distinct objects in memory, although they may still be equal
     */

    /* Polynomials? */
    if (fmpz_poly_length(op1->den) == 1 && fmpz_poly_length(op2->den) == 1)
    {
        const slong len1 = fmpz_poly_length(op1->num);
        const slong len2 = fmpz_poly_length(op2->num);

        fmpz_poly_fit_length(rop->num, FLINT_MAX(len1, len2));
        _fmpq_poly_add(rop->num->coeffs, rop->den->coeffs,
                       op1->num->coeffs, op1->den->coeffs, len1,
                       op2->num->coeffs, op2->den->coeffs, len2);
        _fmpz_poly_set_length(rop->num, FLINT_MAX(len1, len2));
        _fmpz_poly_set_length(rop->den, 1);
        _fmpz_poly_normalise(rop->num);
        return;
    }

    /* Denominators equal to one? */
    if (fmpz_poly_is_one(op1->den))
    {
        fmpz_poly_mul(rop->num, op1->num, op2->den);
        fmpz_poly_add(rop->num, rop->num, op2->num);
        fmpz_poly_set(rop->den, op2->den);
        return;
    }
    if (fmpz_poly_is_one(op2->den))
    {
        fmpz_poly_mul(rop->num, op2->num, op1->den);
        fmpz_poly_add(rop->num, op1->num, rop->num);
        fmpz_poly_set(rop->den, op1->den);
        return;
    }

    /* Henrici's algorithm for summation in quotient fields */

    /*
        We begin by using rop->num as a temporary variable for
        the gcd of the two denominators' greatest common divisor
     */
    fmpz_poly_gcd(rop->num, op1->den, op2->den);

    if (fmpz_poly_is_one(rop->num))
    {
        fmpz_poly_mul(rop->num, op1->num, op2->den);
        fmpz_poly_mul(rop->den, op1->den, op2->num);  /* Using rop->den as temp */
        fmpz_poly_add(rop->num, rop->num, rop->den);
        fmpz_poly_mul(rop->den, op1->den, op2->den);
    }
    else
    {
        /*
            We now copy rop->num into a new variable d, so we
            no longer need rop->num as a temporary variable
         */
        fmpz_poly_init(d);
        fmpz_poly_swap(d, rop->num);

        fmpz_poly_init(r2);
        fmpz_poly_init(s2);

        fmpz_poly_divexact(r2, op1->den, d);  /* +ve leading coeff */
        fmpz_poly_divexact(s2, op2->den, d);  /* +ve leading coeff */

        fmpz_poly_mul(rop->num, op1->num, s2);
        fmpz_poly_mul(rop->den, op2->num, r2);  /* Using rop->den as temp */
        fmpz_poly_add(rop->num, rop->num, rop->den);

        if (fmpz_poly_is_zero(rop->num))
        {
            fmpz_poly_zero(rop->den);
            fmpz_poly_set_coeff_si(rop->den, 0, 1);
        }
        else
        {
            fmpz_poly_mul(rop->den, op1->den, s2);

            fmpz_poly_gcd(r2, rop->num, d);

            if (!fmpz_poly_is_one(r2))
            {
                fmpz_poly_divexact(rop->num, rop->num, r2);
                fmpz_poly_divexact(rop->den, rop->den, r2);
            }
        }

        fmpz_poly_clear(d);
        fmpz_poly_clear(r2);
        fmpz_poly_clear(s2);
    }
}