/* Test mpn_hgcd_appr. Copyright 1991, 1993, 1994, 1996, 1997, 2000-2004, 2011 Free Software Foundation, Inc. This file is part of the GNU MP Library test suite. The GNU MP Library test suite 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; either version 3 of the License, or (at your option) any later version. The GNU MP Library test suite 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. You should have received a copy of the GNU General Public License along with the GNU MP Library test suite. If not, see https://www.gnu.org/licenses/. */ #include #include #include #include "gmp-impl.h" #include "tests.h" static mp_size_t one_test (mpz_t, mpz_t, int); static void debug_mp (mpz_t, int); #define MIN_OPERAND_SIZE 2 struct hgcd_ref { mpz_t m[2][2]; }; static void hgcd_ref_init (struct hgcd_ref *hgcd); static void hgcd_ref_clear (struct hgcd_ref *hgcd); static int hgcd_ref (struct hgcd_ref *hgcd, mpz_t a, mpz_t b); static int hgcd_ref_equal (const struct hgcd_ref *, const struct hgcd_ref *); static int hgcd_appr_valid_p (mpz_t, mpz_t, mp_size_t, struct hgcd_ref *, mpz_t, mpz_t, mp_size_t, struct hgcd_matrix *); static int verbose_flag = 0; int main (int argc, char **argv) { mpz_t op1, op2, temp1, temp2; int i, j, chain_len; gmp_randstate_ptr rands; mpz_t bs; unsigned long size_range; if (argc > 1) { if (strcmp (argv[1], "-v") == 0) verbose_flag = 1; else { fprintf (stderr, "Invalid argument.\n"); return 1; } } tests_start (); rands = RANDS; mpz_init (bs); mpz_init (op1); mpz_init (op2); mpz_init (temp1); mpz_init (temp2); for (i = 0; i < 15; i++) { /* Generate plain operands with unknown gcd. These types of operands have proven to trigger certain bugs in development versions of the gcd code. */ mpz_urandomb (bs, rands, 32); size_range = mpz_get_ui (bs) % 13 + 2; mpz_urandomb (bs, rands, size_range); mpz_urandomb (op1, rands, mpz_get_ui (bs) + MIN_OPERAND_SIZE); mpz_urandomb (bs, rands, size_range); mpz_urandomb (op2, rands, mpz_get_ui (bs) + MIN_OPERAND_SIZE); if (mpz_cmp (op1, op2) < 0) mpz_swap (op1, op2); if (mpz_size (op1) > 0) one_test (op1, op2, i); /* Generate a division chain backwards, allowing otherwise unlikely huge quotients. */ mpz_set_ui (op1, 0); mpz_urandomb (bs, rands, 32); mpz_urandomb (bs, rands, mpz_get_ui (bs) % 16 + 1); mpz_rrandomb (op2, rands, mpz_get_ui (bs)); mpz_add_ui (op2, op2, 1); #if 0 chain_len = 1000000; #else mpz_urandomb (bs, rands, 32); chain_len = mpz_get_ui (bs) % (GMP_NUMB_BITS * GCD_DC_THRESHOLD / 256); #endif for (j = 0; j < chain_len; j++) { mpz_urandomb (bs, rands, 32); mpz_urandomb (bs, rands, mpz_get_ui (bs) % 12 + 1); mpz_rrandomb (temp2, rands, mpz_get_ui (bs) + 1); mpz_add_ui (temp2, temp2, 1); mpz_mul (temp1, op2, temp2); mpz_add (op1, op1, temp1); /* Don't generate overly huge operands. */ if (SIZ (op1) > 3 * GCD_DC_THRESHOLD) break; mpz_urandomb (bs, rands, 32); mpz_urandomb (bs, rands, mpz_get_ui (bs) % 12 + 1); mpz_rrandomb (temp2, rands, mpz_get_ui (bs) + 1); mpz_add_ui (temp2, temp2, 1); mpz_mul (temp1, op1, temp2); mpz_add (op2, op2, temp1); /* Don't generate overly huge operands. */ if (SIZ (op2) > 3 * GCD_DC_THRESHOLD) break; } if (mpz_cmp (op1, op2) < 0) mpz_swap (op1, op2); if (mpz_size (op1) > 0) one_test (op1, op2, i); } mpz_clear (bs); mpz_clear (op1); mpz_clear (op2); mpz_clear (temp1); mpz_clear (temp2); tests_end (); exit (0); } static void debug_mp (mpz_t x, int base) { mpz_out_str (stderr, base, x); fputc ('\n', stderr); } static mp_size_t one_test (mpz_t a, mpz_t b, int i) { struct hgcd_matrix hgcd; struct hgcd_ref ref; mpz_t ref_r0; mpz_t ref_r1; mpz_t hgcd_r0; mpz_t hgcd_r1; int res[2]; mp_size_t asize; mp_size_t bsize; mp_size_t hgcd_init_scratch; mp_size_t hgcd_scratch; mp_ptr hgcd_init_tp; mp_ptr hgcd_tp; mp_limb_t marker[4]; asize = a->_mp_size; bsize = b->_mp_size; ASSERT (asize >= bsize); hgcd_init_scratch = MPN_HGCD_MATRIX_INIT_ITCH (asize); hgcd_init_tp = refmpn_malloc_limbs (hgcd_init_scratch + 2) + 1; mpn_hgcd_matrix_init (&hgcd, asize, hgcd_init_tp); hgcd_scratch = mpn_hgcd_appr_itch (asize); hgcd_tp = refmpn_malloc_limbs (hgcd_scratch + 2) + 1; mpn_random (marker, 4); hgcd_init_tp[-1] = marker[0]; hgcd_init_tp[hgcd_init_scratch] = marker[1]; hgcd_tp[-1] = marker[2]; hgcd_tp[hgcd_scratch] = marker[3]; #if 0 fprintf (stderr, "one_test: i = %d asize = %d, bsize = %d\n", i, a->_mp_size, b->_mp_size); gmp_fprintf (stderr, "one_test: i = %d\n" " a = %Zx\n" " b = %Zx\n", i, a, b); #endif hgcd_ref_init (&ref); mpz_init_set (ref_r0, a); mpz_init_set (ref_r1, b); res[0] = hgcd_ref (&ref, ref_r0, ref_r1); mpz_init_set (hgcd_r0, a); mpz_init_set (hgcd_r1, b); if (bsize < asize) { _mpz_realloc (hgcd_r1, asize); MPN_ZERO (hgcd_r1->_mp_d + bsize, asize - bsize); } res[1] = mpn_hgcd_appr (hgcd_r0->_mp_d, hgcd_r1->_mp_d, asize, &hgcd, hgcd_tp); if (hgcd_init_tp[-1] != marker[0] || hgcd_init_tp[hgcd_init_scratch] != marker[1] || hgcd_tp[-1] != marker[2] || hgcd_tp[hgcd_scratch] != marker[3]) { fprintf (stderr, "ERROR in test %d\n", i); fprintf (stderr, "scratch space overwritten!\n"); if (hgcd_init_tp[-1] != marker[0]) gmp_fprintf (stderr, "before init_tp: %Mx\n" "expected: %Mx\n", hgcd_init_tp[-1], marker[0]); if (hgcd_init_tp[hgcd_init_scratch] != marker[1]) gmp_fprintf (stderr, "after init_tp: %Mx\n" "expected: %Mx\n", hgcd_init_tp[hgcd_init_scratch], marker[1]); if (hgcd_tp[-1] != marker[2]) gmp_fprintf (stderr, "before tp: %Mx\n" "expected: %Mx\n", hgcd_tp[-1], marker[2]); if (hgcd_tp[hgcd_scratch] != marker[3]) gmp_fprintf (stderr, "after tp: %Mx\n" "expected: %Mx\n", hgcd_tp[hgcd_scratch], marker[3]); abort (); } if (!hgcd_appr_valid_p (a, b, res[0], &ref, ref_r0, ref_r1, res[1], &hgcd)) { fprintf (stderr, "ERROR in test %d\n", i); fprintf (stderr, "Invalid results for hgcd and hgcd_ref\n"); fprintf (stderr, "op1="); debug_mp (a, -16); fprintf (stderr, "op2="); debug_mp (b, -16); fprintf (stderr, "hgcd_ref: %ld\n", (long) res[0]); fprintf (stderr, "mpn_hgcd_appr: %ld\n", (long) res[1]); abort (); } refmpn_free_limbs (hgcd_init_tp - 1); refmpn_free_limbs (hgcd_tp - 1); hgcd_ref_clear (&ref); mpz_clear (ref_r0); mpz_clear (ref_r1); mpz_clear (hgcd_r0); mpz_clear (hgcd_r1); return res[0]; } static void hgcd_ref_init (struct hgcd_ref *hgcd) { unsigned i; for (i = 0; i<2; i++) { unsigned j; for (j = 0; j<2; j++) mpz_init (hgcd->m[i][j]); } } static void hgcd_ref_clear (struct hgcd_ref *hgcd) { unsigned i; for (i = 0; i<2; i++) { unsigned j; for (j = 0; j<2; j++) mpz_clear (hgcd->m[i][j]); } } static int sdiv_qr (mpz_t q, mpz_t r, mp_size_t s, const mpz_t a, const mpz_t b) { mpz_fdiv_qr (q, r, a, b); if (mpz_size (r) <= s) { mpz_add (r, r, b); mpz_sub_ui (q, q, 1); } return (mpz_sgn (q) > 0); } static int hgcd_ref (struct hgcd_ref *hgcd, mpz_t a, mpz_t b) { mp_size_t n = MAX (mpz_size (a), mpz_size (b)); mp_size_t s = n/2 + 1; mpz_t q; int res; if (mpz_size (a) <= s || mpz_size (b) <= s) return 0; res = mpz_cmp (a, b); if (res < 0) { mpz_sub (b, b, a); if (mpz_size (b) <= s) return 0; mpz_set_ui (hgcd->m[0][0], 1); mpz_set_ui (hgcd->m[0][1], 0); mpz_set_ui (hgcd->m[1][0], 1); mpz_set_ui (hgcd->m[1][1], 1); } else if (res > 0) { mpz_sub (a, a, b); if (mpz_size (a) <= s) return 0; mpz_set_ui (hgcd->m[0][0], 1); mpz_set_ui (hgcd->m[0][1], 1); mpz_set_ui (hgcd->m[1][0], 0); mpz_set_ui (hgcd->m[1][1], 1); } else return 0; mpz_init (q); for (;;) { ASSERT (mpz_size (a) > s); ASSERT (mpz_size (b) > s); if (mpz_cmp (a, b) > 0) { if (!sdiv_qr (q, a, s, a, b)) break; mpz_addmul (hgcd->m[0][1], q, hgcd->m[0][0]); mpz_addmul (hgcd->m[1][1], q, hgcd->m[1][0]); } else { if (!sdiv_qr (q, b, s, b, a)) break; mpz_addmul (hgcd->m[0][0], q, hgcd->m[0][1]); mpz_addmul (hgcd->m[1][0], q, hgcd->m[1][1]); } } mpz_clear (q); return 1; } static int hgcd_ref_equal (const struct hgcd_ref *A, const struct hgcd_ref *B) { unsigned i; for (i = 0; i<2; i++) { unsigned j; for (j = 0; j<2; j++) if (mpz_cmp (A->m[i][j], B->m[i][j]) != 0) return 0; } return 1; } static int hgcd_appr_valid_p (mpz_t a, mpz_t b, mp_size_t res0, struct hgcd_ref *ref, mpz_t ref_r0, mpz_t ref_r1, mp_size_t res1, struct hgcd_matrix *hgcd) { mp_size_t n = MAX (mpz_size (a), mpz_size (b)); mp_size_t s = n/2 + 1; mp_bitcnt_t dbits, abits, margin; mpz_t appr_r0, appr_r1, t, q; struct hgcd_ref appr; if (!res0) { if (!res1) return 1; fprintf (stderr, "mpn_hgcd_appr returned 1 when no reduction possible.\n"); return 0; } /* NOTE: No *_clear calls on error return, since we're going to abort anyway. */ mpz_init (t); mpz_init (q); hgcd_ref_init (&appr); mpz_init (appr_r0); mpz_init (appr_r1); if (mpz_size (ref_r0) <= s) { fprintf (stderr, "ref_r0 too small!!!: "); debug_mp (ref_r0, 16); return 0; } if (mpz_size (ref_r1) <= s) { fprintf (stderr, "ref_r1 too small!!!: "); debug_mp (ref_r1, 16); return 0; } mpz_sub (t, ref_r0, ref_r1); dbits = mpz_sizeinbase (t, 2); if (dbits > s*GMP_NUMB_BITS) { fprintf (stderr, "ref |r0 - r1| too large!!!: "); debug_mp (t, 16); return 0; } if (!res1) { mpz_set (appr_r0, a); mpz_set (appr_r1, b); } else { unsigned i; for (i = 0; i<2; i++) { unsigned j; for (j = 0; j<2; j++) { mp_size_t mn = hgcd->n; MPN_NORMALIZE (hgcd->p[i][j], mn); mpz_realloc (appr.m[i][j], mn); MPN_COPY (PTR (appr.m[i][j]), hgcd->p[i][j], mn); SIZ (appr.m[i][j]) = mn; } } mpz_mul (appr_r0, appr.m[1][1], a); mpz_mul (t, appr.m[0][1], b); mpz_sub (appr_r0, appr_r0, t); if (mpz_sgn (appr_r0) <= 0 || mpz_size (appr_r0) <= s) { fprintf (stderr, "appr_r0 too small: "); debug_mp (appr_r0, 16); return 0; } mpz_mul (appr_r1, appr.m[1][0], a); mpz_mul (t, appr.m[0][0], b); mpz_sub (appr_r1, t, appr_r1); if (mpz_sgn (appr_r1) <= 0 || mpz_size (appr_r1) <= s) { fprintf (stderr, "appr_r1 too small: "); debug_mp (appr_r1, 16); return 0; } } mpz_sub (t, appr_r0, appr_r1); abits = mpz_sizeinbase (t, 2); if (abits < dbits) { fprintf (stderr, "|r0 - r1| too small: "); debug_mp (t, 16); return 0; } /* We lose one bit each time we discard the least significant limbs. For the lehmer code, that can happen at most s * (GMP_NUMB_BITS) / (GMP_NUMB_BITS - 1) times. For the dc code, we lose an entire limb (or more?) for each level of recursion. */ margin = (n/2+1) * GMP_NUMB_BITS / (GMP_NUMB_BITS - 1); { mp_size_t rn; for (rn = n; ABOVE_THRESHOLD (rn, HGCD_APPR_THRESHOLD); rn = (rn + 1)/2) margin += GMP_NUMB_BITS; } if (verbose_flag && abits > dbits) fprintf (stderr, "n = %u: sbits = %u: ref #(r0-r1): %u, appr #(r0-r1): %u excess: %d, margin: %u\n", (unsigned) n, (unsigned) s*GMP_NUMB_BITS, (unsigned) dbits, (unsigned) abits, (int) (abits - s * GMP_NUMB_BITS), (unsigned) margin); if (abits > s*GMP_NUMB_BITS + margin) { fprintf (stderr, "appr |r0 - r1| much larger than minimal (by %u bits, margin = %u bits)\n", (unsigned) (abits - s*GMP_NUMB_BITS), (unsigned) margin); return 0; } while (mpz_cmp (appr_r0, ref_r0) > 0 || mpz_cmp (appr_r1, ref_r1) > 0) { ASSERT (mpz_size (appr_r0) > s); ASSERT (mpz_size (appr_r1) > s); if (mpz_cmp (appr_r0, appr_r1) > 0) { if (!sdiv_qr (q, appr_r0, s, appr_r0, appr_r1)) break; mpz_addmul (appr.m[0][1], q, appr.m[0][0]); mpz_addmul (appr.m[1][1], q, appr.m[1][0]); } else { if (!sdiv_qr (q, appr_r1, s, appr_r1, appr_r0)) break; mpz_addmul (appr.m[0][0], q, appr.m[0][1]); mpz_addmul (appr.m[1][0], q, appr.m[1][1]); } } if (mpz_cmp (appr_r0, ref_r0) != 0 || mpz_cmp (appr_r1, ref_r1) != 0 || !hgcd_ref_equal (ref, &appr)) { fprintf (stderr, "appr_r0: "); debug_mp (appr_r0, 16); fprintf (stderr, "ref_r0: "); debug_mp (ref_r0, 16); fprintf (stderr, "appr_r1: "); debug_mp (appr_r1, 16); fprintf (stderr, "ref_r1: "); debug_mp (ref_r1, 16); return 0; } mpz_clear (t); mpz_clear (q); hgcd_ref_clear (&appr); mpz_clear (appr_r0); mpz_clear (appr_r1); return 1; }