/* mpq_cmp(u,v) -- Compare U, V. Return positive, zero, or negative based on if U > V, U == V, or U < V. Copyright 1991, 1994, 1996, 2001, 2002, 2005 Free Software Foundation, Inc. This file is part of the GNU MP Library. The GNU MP Library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser 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 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the GNU MP Library. If not, see https://www.gnu.org/licenses/. */ #include "gmp.h" #include "gmp-impl.h" #include "longlong.h" int mpq_cmp (const mpq_t op1, const mpq_t op2) { mp_size_t num1_size = SIZ(NUM(op1)); mp_size_t den1_size = SIZ(DEN(op1)); mp_size_t num2_size = SIZ(NUM(op2)); mp_size_t den2_size = SIZ(DEN(op2)); mp_size_t tmp1_size, tmp2_size; mp_ptr tmp1_ptr, tmp2_ptr; mp_size_t num1_sign; int cc; TMP_DECL; /* need canonical signs to get right result */ ASSERT (den1_size > 0); ASSERT (den2_size > 0); if (num1_size == 0) return -num2_size; if (num2_size == 0) return num1_size; if ((num1_size ^ num2_size) < 0) /* I.e. are the signs different? */ return num1_size; num1_sign = num1_size; num1_size = ABS (num1_size); num2_size = ABS (num2_size); tmp1_size = num1_size + den2_size; tmp2_size = num2_size + den1_size; /* 1. Check to see if we can tell which operand is larger by just looking at the number of limbs. */ /* NUM1 x DEN2 is either TMP1_SIZE limbs or TMP1_SIZE-1 limbs. Same for NUM1 x DEN1 with respect to TMP2_SIZE. */ if (tmp1_size > tmp2_size + 1) /* NUM1 x DEN2 is surely larger in magnitude than NUM2 x DEN1. */ return num1_sign; if (tmp2_size > tmp1_size + 1) /* NUM1 x DEN2 is surely smaller in magnitude than NUM2 x DEN1. */ return -num1_sign; /* 2. Same, but compare the number of significant bits. */ { int cnt1, cnt2; mp_bitcnt_t bits1, bits2; count_leading_zeros (cnt1, PTR(NUM(op1))[num1_size - 1]); count_leading_zeros (cnt2, PTR(DEN(op2))[den2_size - 1]); bits1 = tmp1_size * GMP_NUMB_BITS - cnt1 - cnt2 + 2 * GMP_NAIL_BITS; count_leading_zeros (cnt1, PTR(NUM(op2))[num2_size - 1]); count_leading_zeros (cnt2, PTR(DEN(op1))[den1_size - 1]); bits2 = tmp2_size * GMP_NUMB_BITS - cnt1 - cnt2 + 2 * GMP_NAIL_BITS; if (bits1 > bits2 + 1) return num1_sign; if (bits2 > bits1 + 1) return -num1_sign; } /* 3. Finally, cross multiply and compare. */ TMP_MARK; TMP_ALLOC_LIMBS_2 (tmp1_ptr,tmp1_size, tmp2_ptr,tmp2_size); if (num1_size >= den2_size) tmp1_size -= 0 == mpn_mul (tmp1_ptr, PTR(NUM(op1)), num1_size, PTR(DEN(op2)), den2_size); else tmp1_size -= 0 == mpn_mul (tmp1_ptr, PTR(DEN(op2)), den2_size, PTR(NUM(op1)), num1_size); if (num2_size >= den1_size) tmp2_size -= 0 == mpn_mul (tmp2_ptr, PTR(NUM(op2)), num2_size, PTR(DEN(op1)), den1_size); else tmp2_size -= 0 == mpn_mul (tmp2_ptr, PTR(DEN(op1)), den1_size, PTR(NUM(op2)), num2_size); cc = tmp1_size - tmp2_size != 0 ? tmp1_size - tmp2_size : mpn_cmp (tmp1_ptr, tmp2_ptr, tmp1_size); TMP_FREE; return num1_sign < 0 ? -cc : cc; }