/*
Copyright (C) 2017 Daniel Schultz
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 "nmod_mpoly.h"
int
main(void)
{
int i, j, result, ok1, ok2;
FLINT_TEST_INIT(state);
flint_printf("divides_monagan_pearce....");
fflush(stdout);
/* Check f*g/g = f */
for (i = 0; i < 100 * flint_test_multiplier(); i++)
{
nmod_mpoly_ctx_t ctx;
nmod_mpoly_t f, g, h, k;
slong len, len1, len2;
flint_bitcnt_t exp_bits, exp_bits1, exp_bits2;
mp_limb_t modulus;
modulus = n_randint(state, FLINT_BITS - 1) + 1;
modulus = n_randbits(state, modulus);
modulus = n_nextprime(modulus, 1);
nmod_mpoly_ctx_init_rand(ctx, state, 20, modulus);
nmod_mpoly_init(f, ctx);
nmod_mpoly_init(g, ctx);
nmod_mpoly_init(h, ctx);
nmod_mpoly_init(k, ctx);
len = n_randint(state, 10);
len1 = n_randint(state, 10);
len2 = n_randint(state, 10) + 1;
exp_bits = n_randint(state, 200) + 2;
exp_bits1 = n_randint(state, 200) + 2;
exp_bits2 = n_randint(state, 200) + 2;
for (j = 0; j < 4; j++)
{
nmod_mpoly_randtest_bits(f, state, len1, exp_bits1, ctx);
nmod_mpoly_randtest_bits(g, state, len2, exp_bits2, ctx);
if (nmod_mpoly_is_zero(g, ctx))
nmod_mpoly_one(g, ctx);
nmod_mpoly_randtest_bits(h, state, len, exp_bits, ctx);
nmod_mpoly_randtest_bits(k, state, len, exp_bits, ctx);
nmod_mpoly_mul_johnson(h, f, g, ctx);
nmod_mpoly_assert_canonical(h, ctx);
ok1 = nmod_mpoly_divides_monagan_pearce(k, h, g, ctx);
nmod_mpoly_assert_canonical(k, ctx);
result = (ok1 && nmod_mpoly_equal(f, k, ctx));
if (!result)
{
printf("FAIL\n");
flint_printf("Check f*g/g = f\ni = %wd, j = %wd\n", i ,j);
flint_abort();
}
}
nmod_mpoly_clear(f, ctx);
nmod_mpoly_clear(g, ctx);
nmod_mpoly_clear(h, ctx);
nmod_mpoly_clear(k, ctx);
nmod_mpoly_ctx_clear(ctx);
}
/* Check random polys don't divide */
for (i = 0; i < 10 * flint_test_multiplier(); i++)
{
nmod_mpoly_ctx_t ctx;
nmod_mpoly_t f, g, h, k;
ordering_t ord;
mp_limb_t modulus;
slong nvars, len, len1, len2, exp_bound, exp_bound1, exp_bound2;
ord = mpoly_ordering_randtest(state);
nvars = n_randint(state, 10) + 1;
modulus = n_randint(state, FLINT_BITS - 1) + 1;
modulus = n_randbits(state, modulus);
modulus = n_nextprime(modulus, 1);
nmod_mpoly_ctx_init(ctx, nvars, ord, modulus);
nmod_mpoly_init(f, ctx);
nmod_mpoly_init(g, ctx);
nmod_mpoly_init(h, ctx);
nmod_mpoly_init(k, ctx);
len = n_randint(state, 20);
len1 = n_randint(state, 20);
len2 = n_randint(state, 20) + 1;
exp_bound = n_randint(state, 200/nvars + 1) + 1;
exp_bound1 = n_randint(state, 200/nvars + 1) + 1;
exp_bound2 = n_randint(state, 200/nvars + 1) + 1;
for (j = 0; j < 4; j++)
{
nmod_mpoly_randtest_bound(f, state, len1, exp_bound1, ctx);
nmod_mpoly_randtest_bound(g, state, len2, exp_bound2, ctx);
if (nmod_mpoly_is_zero(g, ctx))
nmod_mpoly_one(g, ctx);
nmod_mpoly_randtest_bound(h, state, len, exp_bound, ctx);
nmod_mpoly_randtest_bound(k, state, len, exp_bound, ctx);
ok1 = nmod_mpoly_divides_monagan_pearce(h, f, g, ctx);
nmod_mpoly_assert_canonical(h, ctx);
if (ok1)
{
nmod_mpoly_mul_johnson(k, h, g, ctx);
nmod_mpoly_assert_canonical(k, ctx);
}
result = (ok1 == 0 || nmod_mpoly_equal(f, k, ctx));
if (!result)
{
printf("FAIL\n");
flint_printf("Check random polys don't divide\ni = %wd, j = %wd\n", i, j);
flint_abort();
}
}
nmod_mpoly_clear(f, ctx);
nmod_mpoly_clear(g, ctx);
nmod_mpoly_clear(h, ctx);
nmod_mpoly_clear(k, ctx);
nmod_mpoly_ctx_clear(ctx);
}
/* Check aliasing first argument, exact division */
for (i = 0; i < 10 * flint_test_multiplier(); i++)
{
nmod_mpoly_ctx_t ctx;
nmod_mpoly_t f, g, h, k;
ordering_t ord;
mp_limb_t modulus;
slong nvars, len, len1, len2;
slong exp_bits, exp_bits1, exp_bits2;
ord = mpoly_ordering_randtest(state);
nvars = n_randint(state, 10) + 1;
modulus = n_randint(state, FLINT_BITS - 1) + 1;
modulus = n_randbits(state, modulus);
modulus = n_nextprime(modulus, 1);
nmod_mpoly_ctx_init(ctx, nvars, ord, modulus);
nmod_mpoly_init(f, ctx);
nmod_mpoly_init(g, ctx);
nmod_mpoly_init(h, ctx);
nmod_mpoly_init(k, ctx);
len = n_randint(state, 50);
len1 = n_randint(state, 50);
len2 = n_randint(state, 50) + 1;
exp_bits = n_randint(state, 200) + 2;
exp_bits1 = n_randint(state, 200) + 2;
exp_bits2 = n_randint(state, 200) + 2;
for (j = 0; j < 4; j++)
{
nmod_mpoly_randtest_bits(f, state, len1, exp_bits1, ctx);
nmod_mpoly_randtest_bits(g, state, len2, exp_bits2, ctx);
if (nmod_mpoly_is_zero(g, ctx))
nmod_mpoly_one(g, ctx);
nmod_mpoly_randtest_bits(h, state, len, exp_bits, ctx);
nmod_mpoly_randtest_bits(k, state, len, exp_bits, ctx);
nmod_mpoly_mul_johnson(h, f, g, ctx);
nmod_mpoly_assert_canonical(h, ctx);
ok1 = nmod_mpoly_divides_monagan_pearce(k, h, g, ctx);
nmod_mpoly_assert_canonical(k, ctx);
ok2 = nmod_mpoly_divides_monagan_pearce(h, h, g, ctx);
nmod_mpoly_assert_canonical(h, ctx);
result = (ok1 == 1 && ok2 == 1 && nmod_mpoly_equal(h, k, ctx));
if (!result)
{
printf("FAIL\n");
flint_printf("Check aliasing first argument, exact division\ni = %wd, j = %wd\n", i, j);
flint_abort();
}
}
nmod_mpoly_clear(f, ctx);
nmod_mpoly_clear(g, ctx);
nmod_mpoly_clear(h, ctx);
nmod_mpoly_clear(k, ctx);
nmod_mpoly_ctx_clear(ctx);
}
/* Check aliasing, first argument, random polys */
for (i = 0; i < 10 * flint_test_multiplier(); i++)
{
nmod_mpoly_ctx_t ctx;
nmod_mpoly_t f, g, h;
ordering_t ord;
mp_limb_t modulus;
slong nvars, len, len1, len2, exp_bound, exp_bound1, exp_bound2;
ord = mpoly_ordering_randtest(state);
nvars = n_randint(state, 10) + 1;
modulus = n_randint(state, FLINT_BITS - 1) + 1;
modulus = n_randbits(state, modulus);
modulus = n_nextprime(modulus, 1);
nmod_mpoly_ctx_init(ctx, nvars, ord, modulus);
nmod_mpoly_init(f, ctx);
nmod_mpoly_init(g, ctx);
nmod_mpoly_init(h, ctx);
len = n_randint(state, 20);
len1 = n_randint(state, 20);
len2 = n_randint(state, 20) + 1;
exp_bound = n_randint(state, 200/nvars + 1) + 1;
exp_bound1 = n_randint(state, 200/nvars + 1) + 1;
exp_bound2 = n_randint(state, 200/nvars + 1) + 1;
for (j = 0; j < 4; j++)
{
nmod_mpoly_randtest_bound(f, state, len1, exp_bound1, ctx);
nmod_mpoly_randtest_bound(g, state, len2, exp_bound2, ctx);
if (nmod_mpoly_is_zero(g, ctx))
nmod_mpoly_one(g, ctx);
nmod_mpoly_randtest_bound(h, state, len, exp_bound, ctx);
ok1 = nmod_mpoly_divides_monagan_pearce(h, f, g, ctx);
nmod_mpoly_assert_canonical(h, ctx);
ok2 = nmod_mpoly_divides_monagan_pearce(f, f, g, ctx);
nmod_mpoly_assert_canonical(f, ctx);
result = ((ok1 == ok2) && (ok1 == 0 || nmod_mpoly_equal(f, h, ctx)));
if (!result)
{
printf("FAIL\n");
flint_printf("Check aliasing, first argument, random polys\ni = %wd, j = %wd\n", i, j);
flint_abort();
}
}
nmod_mpoly_clear(f, ctx);
nmod_mpoly_clear(g, ctx);
nmod_mpoly_clear(h, ctx);
nmod_mpoly_ctx_clear(ctx);
}
/* Check aliasing second argument, exact division */
for (i = 0; i < 10 * flint_test_multiplier(); i++)
{
nmod_mpoly_ctx_t ctx;
nmod_mpoly_t f, g, h, k;
ordering_t ord;
mp_limb_t modulus;
slong nvars, len, len1, len2;
slong exp_bits, exp_bits1, exp_bits2;
ord = mpoly_ordering_randtest(state);
nvars = n_randint(state, 10) + 1;
modulus = n_randint(state, FLINT_BITS - 1) + 1;
modulus = n_randbits(state, modulus);
modulus = n_nextprime(modulus, 1);
nmod_mpoly_ctx_init(ctx, nvars, ord, modulus);
nmod_mpoly_init(f, ctx);
nmod_mpoly_init(g, ctx);
nmod_mpoly_init(h, ctx);
nmod_mpoly_init(k, ctx);
len = n_randint(state, 50);
len1 = n_randint(state, 50);
len2 = n_randint(state, 50) + 1;
exp_bits = n_randint(state, 200) + 2;
exp_bits1 = n_randint(state, 200) + 2;
exp_bits2 = n_randint(state, 200) + 2;
for (j = 0; j < 4; j++)
{
nmod_mpoly_randtest_bits(f, state, len1, exp_bits1, ctx);
nmod_mpoly_randtest_bits(g, state, len2, exp_bits2, ctx);
if (nmod_mpoly_is_zero(g, ctx))
nmod_mpoly_one(g, ctx);
nmod_mpoly_randtest_bits(h, state, len, exp_bits, ctx);
nmod_mpoly_randtest_bits(k, state, len, exp_bits, ctx);
nmod_mpoly_mul_johnson(h, f, g, ctx);
nmod_mpoly_assert_canonical(h, ctx);
ok1 = nmod_mpoly_divides_monagan_pearce(k, h, g, ctx);
nmod_mpoly_assert_canonical(k, ctx);
ok2 = nmod_mpoly_divides_monagan_pearce(g, h, g, ctx);
nmod_mpoly_assert_canonical(g, ctx);
result = (ok1 == 1 && ok2 == 1 && nmod_mpoly_equal(g, k, ctx));
if (!result)
{
printf("FAIL\n");
flint_printf("Check aliasing second argument, exact division\ni = %wd, j = %wd\n", i, j);
flint_abort();
}
}
nmod_mpoly_clear(f, ctx);
nmod_mpoly_clear(g, ctx);
nmod_mpoly_clear(h, ctx);
nmod_mpoly_clear(k, ctx);
nmod_mpoly_ctx_clear(ctx);
}
/* Check aliasing, second argument, random polys */
for (i = 0; i < 10 * flint_test_multiplier(); i++)
{
nmod_mpoly_ctx_t ctx;
nmod_mpoly_t f, g, h;
ordering_t ord;
mp_limb_t modulus;
slong nvars, len, len1, len2, exp_bound, exp_bound1, exp_bound2;
ord = mpoly_ordering_randtest(state);
nvars = n_randint(state, 10) + 1;
modulus = n_randint(state, FLINT_BITS - 1) + 1;
modulus = n_randbits(state, modulus);
modulus = n_nextprime(modulus, 1);
nmod_mpoly_ctx_init(ctx, nvars, ord, modulus);
nmod_mpoly_init(f, ctx);
nmod_mpoly_init(g, ctx);
nmod_mpoly_init(h, ctx);
len = n_randint(state, 100);
len1 = n_randint(state, 100);
len2 = n_randint(state, 100) + 1;
exp_bound = n_randint(state, 200/nvars + 1) + 1;
exp_bound1 = n_randint(state, 200/nvars + 1) + 1;
exp_bound2 = n_randint(state, 200/nvars + 1) + 1;
for (j = 0; j < 4; j++)
{
nmod_mpoly_randtest_bound(f, state, len1, exp_bound1, ctx);
nmod_mpoly_randtest_bound(g, state, len2, exp_bound2, ctx);
if (nmod_mpoly_is_zero(g, ctx))
nmod_mpoly_one(g, ctx);
nmod_mpoly_randtest_bound(h, state, len, exp_bound, ctx);
ok1 = nmod_mpoly_divides_monagan_pearce(h, f, g, ctx);
nmod_mpoly_assert_canonical(h, ctx);
ok2 = nmod_mpoly_divides_monagan_pearce(g, f, g, ctx);
nmod_mpoly_assert_canonical(g, ctx);
result = ((ok1 == ok2) && (ok1 == 0 || nmod_mpoly_equal(g, h, ctx)));
if (!result)
{
printf("FAIL\n");
flint_printf("Check aliasing, second argument, random polys\ni = %wd, j = %wd\n", i, j);
flint_abort();
}
}
nmod_mpoly_clear(f, ctx);
nmod_mpoly_clear(g, ctx);
nmod_mpoly_clear(h, ctx);
nmod_mpoly_ctx_clear(ctx);
}
FLINT_TEST_CLEANUP(state);
flint_printf("PASS\n");
return 0;
}