/* Copyright (C) 2010 William Hart 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 2.1 of the License, or (at your option) any later version. See . */ #include #include #include "flint.h" #include "fmpz.h" #include "fmpz_vec.h" #include "fmpz_poly.h" #include "ulong_extras.h" /* Implements karatsuba multiplication. There is no basecase crossover, so this is only efficient when the coefficients are large (the main usage case). The algorithm is the "odd/even" Karatsuba algorithm. Let f(x) = f1(x^2) + x*f2(x^2), g(x) = g1(x^2) + x*g2(x^2), then f(x)*g(x) = f1(x^2)*g1(x^2) + x^2*f2(x^2)*g2(x^2) + x*((f1(x^2) + f2(x^2))*(g1(x^2) + g2(x^2)) - f1(x^2)*g1(x^2) - f2(x^2)*g2(x^2)). Thus only three multiplications are performed (and numerous additions and subtractions). Instead of working with polynomials with the usual ordering, reverse binary ordering is used, i.e. for length 2^3 (zero padded) terms of degree 110 and 011 in binary are swapped, etc. The advantage of working in this format is that the first half of the coefficients of f will be the coefficients of f1, and the second half, those of f2, etc. This applies right down the recursion. The only tricky bit is when multiplying by x. One must undo the revbin to shift by one term to the left. */ void _fmpz_poly_mul_kara_recursive(fmpz * out, fmpz * rev1, fmpz * rev2, fmpz * temp, slong bits); /* Switches the coefficients of poly in of length len into a poly out of length 2^bits. */ void revbin1(fmpz * out, const fmpz * in, slong len, slong bits) { slong i; for (i = 0; i < len; i++) out[n_revbin(i, bits)] = in[i]; } /* Switches the coefficients of poly in of length 2^bits into a poly out of length len. */ void revbin2(fmpz * out, const fmpz * in, slong len, slong bits) { slong i; for (i = 0; i < len; i++) out[i] = in[n_revbin(i, bits)]; } /* in1 += x*in2 assuming both in1 and in2 are revbin'd. */ void _fmpz_vec_add_rev(fmpz * in1, fmpz * in2, slong bits) { slong i; for (i = 0; i < (WORD(1) << bits) - 1; i++) { slong j = n_revbin(n_revbin(i, bits) + 1, bits); fmpz_add(in1 + j, in1 + j, in2 + i); } } /* Recursive Karatsuba assuming polynomials are in revbin format. Assumes rev1 and rev2 are both of length 2^bits and that temp has space for 2^bits coefficients. */ void _fmpz_poly_mul_kara_recursive(fmpz * out, fmpz * rev1, fmpz * rev2, fmpz * temp, slong bits) { slong length = (WORD(1) << bits); slong m = length / 2; if (length == 1) { fmpz_mul(out, rev1, rev2); fmpz_zero(out + 1); return; } _fmpz_vec_add(temp, rev1, rev1 + m, m); _fmpz_vec_add(temp + m, rev2, rev2 + m, m); _fmpz_poly_mul_kara_recursive(out, rev1, rev2, temp + 2 * m, bits - 1); _fmpz_poly_mul_kara_recursive(out + length, temp, temp + m, temp + 2 * m, bits - 1); _fmpz_poly_mul_kara_recursive(temp, rev1 + m, rev2 + m, temp + 2 * m, bits - 1); _fmpz_vec_sub(out + length, out + length, out, length); _fmpz_vec_sub(out + length, out + length, temp, length); _fmpz_vec_add_rev(out, temp, bits); } /* Assumes poly1 and poly2 are not length 0 and len1 >= len2. */ void _fmpz_poly_mul_karatsuba(fmpz * res, const fmpz * poly1, slong len1, const fmpz * poly2, slong len2) { fmpz *rev1, *rev2, *out, *temp; slong length, loglen = 0; if (len1 == 1) { fmpz_mul(res, poly1, poly2); return; } while ((WORD(1) << loglen) < len1) loglen++; length = (WORD(1) << loglen); rev1 = (fmpz *) flint_calloc(4 * length, sizeof(fmpz *)); rev2 = rev1 + length; out = rev1 + 2 * length; temp = _fmpz_vec_init(2 * length); revbin1(rev1, poly1, len1, loglen); revbin1(rev2, poly2, len2, loglen); _fmpz_poly_mul_kara_recursive(out, rev1, rev2, temp, loglen); _fmpz_vec_zero(res, len1 + len2 - 1); revbin2(res, out, len1 + len2 - 1, loglen + 1); _fmpz_vec_clear(temp, 2 * length); flint_free(rev1); } void fmpz_poly_mul_karatsuba(fmpz_poly_t res, const fmpz_poly_t poly1, const fmpz_poly_t poly2) { slong len_out; if ((poly1->length == 0) || (poly2->length == 0)) { fmpz_poly_zero(res); return; } len_out = poly1->length + poly2->length - 1; fmpz_poly_fit_length(res, len_out); if (poly1->length >= poly2->length) _fmpz_poly_mul_karatsuba(res->coeffs, poly1->coeffs, poly1->length, poly2->coeffs, poly2->length); else _fmpz_poly_mul_karatsuba(res->coeffs, poly2->coeffs, poly2->length, poly1->coeffs, poly1->length); _fmpz_poly_set_length(res, len_out); }