xref: /netbsd-src/external/lgpl3/gmp/dist/mpz/ior.c (revision 72c7faa4dbb41dbb0238d6b4a109da0d4b236dd4) 
1 /* mpz_ior -- Logical inclusive or.
2 
3 Copyright 1991, 1993, 1994, 1996, 1997, 2000, 2001, 2005, 2012, 2013,
4 2015-2018 Free Software Foundation, Inc.
5 
6 This file is part of the GNU MP Library.
7 
8 The GNU MP Library is free software; you can redistribute it and/or modify
9 it under the terms of either:
10 
11   * the GNU Lesser General Public License as published by the Free
12     Software Foundation; either version 3 of the License, or (at your
13     option) any later version.
14 
15 or
16 
17   * the GNU General Public License as published by the Free Software
18     Foundation; either version 2 of the License, or (at your option) any
19     later version.
20 
21 or both in parallel, as here.
22 
23 The GNU MP Library is distributed in the hope that it will be useful, but
24 WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
25 or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
26 for more details.
27 
28 You should have received copies of the GNU General Public License and the
29 GNU Lesser General Public License along with the GNU MP Library.  If not,
30 see https://www.gnu.org/licenses/.  */
31 
32 #include "gmp-impl.h"
33 
34 void
mpz_ior(mpz_ptr res,mpz_srcptr op1,mpz_srcptr op2)35 mpz_ior (mpz_ptr res, mpz_srcptr op1, mpz_srcptr op2)
36 {
37   mp_srcptr op1_ptr, op2_ptr;
38   mp_size_t op1_size, op2_size;
39   mp_ptr res_ptr;
40   mp_size_t res_size;
41   mp_size_t i;
42 
43   op1_size = SIZ(op1);
44   op2_size = SIZ(op2);
45 
46   if (op1_size < op2_size)
47     {
48       MPZ_SRCPTR_SWAP (op1, op2);
49       MP_SIZE_T_SWAP (op1_size, op2_size);
50     }
51 
52   op1_ptr = PTR(op1);
53   res_ptr = PTR(res);
54 
55   if (op2_size >= 0)
56     {
57       if (res_ptr != op1_ptr)
58 	{
59 	  res_ptr = MPZ_REALLOC (res, op1_size);
60 	  /* No overlapping possible: op1_ptr = PTR(op1); */
61 	  MPN_COPY (res_ptr + op2_size, op1_ptr + op2_size,
62 		    op1_size - op2_size);
63 	}
64       if (LIKELY (op2_size != 0))
65 	mpn_ior_n (res_ptr, op1_ptr, PTR(op2), op2_size);
66 
67       SIZ(res) = op1_size;
68     }
69   else
70     {
71       mp_ptr opx;
72       TMP_DECL;
73 
74       TMP_MARK;
75       if (op1_size < 0)
76 	{
77 	  mp_ptr opy;
78 
79 	  /* Both operands are negative, so will be the result.
80 	     -((-OP1) | (-OP2)) = -(~(OP1 - 1) | ~(OP2 - 1)) =
81 	     = ~(~(OP1 - 1) | ~(OP2 - 1)) + 1 =
82 	     = ((OP1 - 1) & (OP2 - 1)) + 1      */
83 
84 	  res_size = -op1_size;
85 
86 	  /* Possible optimization: Decrease mpn_sub precision,
87 	     as we won't use the entire res of both.  */
88 	  TMP_ALLOC_LIMBS_2 (opx, res_size, opy, res_size);
89 	  mpn_sub_1 (opx, op1_ptr, res_size, (mp_limb_t) 1);
90 	  op1_ptr = opx;
91 
92 	  mpn_sub_1 (opy, PTR(op2), res_size, (mp_limb_t) 1);
93 	  op2_ptr = opy;
94 
95 	  /* First loop finds the size of the result.  */
96 	  for (i = res_size; --i >= 0;)
97 	    if ((op1_ptr[i] & op2_ptr[i]) != 0)
98 	      break;
99 	  res_size = i + 1;
100 
101 	  res_ptr = MPZ_NEWALLOC (res, res_size + 1);
102 
103 	  if (res_size != 0)
104 	    {
105 	      /* Second loop computes the real result.  */
106 	      mpn_and_n (res_ptr, op1_ptr, op2_ptr, res_size);
107 
108 	      res_ptr[res_size] = 0;
109 	      MPN_INCR_U (res_ptr, res_size + 1, 1);
110 	      res_size += res_ptr[res_size];
111 	    }
112 	  else
113 	    {
114 	      res_ptr[0] = 1;
115 	      res_size = 1;
116 	    }
117 
118 	  SIZ(res) = -res_size;
119 	}
120       else
121 	{
122 	  mp_limb_t cy;
123 	  mp_size_t count;
124 
125 	  /* Operand 2 negative, so will be the result.
126 	     -(OP1 | (-OP2)) = -(OP1 | ~(OP2 - 1)) =
127 	     = ~(OP1 | ~(OP2 - 1)) + 1 =
128 	     = (~OP1 & (OP2 - 1)) + 1      */
129 
130 	  op2_size = -op2_size;
131 
132 	  res_ptr = MPZ_REALLOC (res, op2_size);
133 	  op1_ptr = PTR(op1);
134 
135 	  opx = TMP_ALLOC_LIMBS (op2_size);
136 	  mpn_sub_1 (opx, PTR(op2), op2_size, (mp_limb_t) 1);
137 	  op2_ptr = opx;
138 	  op2_size -= op2_ptr[op2_size - 1] == 0;
139 
140 	  if (op1_size >= op2_size)
141 	    {
142 	      /* We can just ignore the part of OP1 that stretches above OP2,
143 		 because the result limbs are zero there.  */
144 
145 	      /* First loop finds the size of the result.  */
146 	      for (i = op2_size; --i >= 0;)
147 		if ((~op1_ptr[i] & op2_ptr[i]) != 0)
148 		  break;
149 	      res_size = i + 1;
150 	      count = res_size;
151 	    }
152 	  else
153 	    {
154 	      res_size = op2_size;
155 
156 	      /* Copy the part of OP2 that stretches above OP1, to RES.  */
157 	      MPN_COPY (res_ptr + op1_size, op2_ptr + op1_size, op2_size - op1_size);
158 	      count = op1_size;
159 	    }
160 
161 	  if (res_size != 0)
162 	    {
163 	      /* Second loop computes the real result.  */
164 	      if (LIKELY (count != 0))
165 		mpn_andn_n (res_ptr, op2_ptr, op1_ptr, count);
166 
167 	      cy = mpn_add_1 (res_ptr, res_ptr, res_size, (mp_limb_t) 1);
168 	      if (cy)
169 		{
170 		  res_ptr[res_size] = cy;
171 		  ++res_size;
172 		}
173 	    }
174 	  else
175 	    {
176 	      res_ptr[0] = 1;
177 	      res_size = 1;
178 	    }
179 
180 	  SIZ(res) = -res_size;
181 	}
182       TMP_FREE;
183     }
184 }
185