/src/ghostpdl/psi/zarith.c

Source (jump to first uncovered line)
/* Copyright (C) 2001-2023 Artifex Software, Inc.
   All Rights Reserved.

   This software is provided AS-IS with no warranty, either express or
   implied.

   This software is distributed under license and may not be copied,
   modified or distributed except as expressly authorized under the terms
   of the license contained in the file LICENSE in this distribution.

   Refer to licensing information at http://www.artifex.com or contact
   Artifex Software, Inc.,  39 Mesa Street, Suite 108A, San Francisco,
   CA 94129, USA, for further information.
*/


/* Arithmetic operators */
#include "math_.h"
#include "ghost.h"
#include "oper.h"
#include "store.h"
#include "gsstate.h"

/*
 * Many of the procedures in this file are public only so they can be
 * called from the FunctionType 4 interpreter (zfunc4.c).
 */

static int mul_64_64_overflowcheck(int64_t abc, int64_t def, int64_t *res);

/* <num1> <num2> add <sum> */
/* We make this into a separate procedure because */
/* the interpreter will almost always call it directly. */
int
zop_add(i_ctx_t *i_ctx_p)
{
    register os_ptr op = osp;
    float result;

    check_op(2);
    switch (r_type(op)) {
    default:
        return_op_typecheck(op);
    case t_real:
        switch (r_type(op - 1)) {
        default:
            return_op_typecheck(op - 1);
        case t_real:
            result = op[-1].value.realval + op->value.realval;
#ifdef HAVE_ISINF
            if (isinf(result))
                return_error(gs_error_undefinedresult);
#endif
#ifdef HAVE_ISNAN
            if (isnan(result))
                return_error(gs_error_undefinedresult);
#endif
            op[-1].value.realval = result;
            break;
        case t_integer:
            make_real(op - 1, (double)op[-1].value.intval + op->value.realval);
        }
        break;
    case t_integer:
        switch (r_type(op - 1)) {
        default:
            return_op_typecheck(op - 1);
        case t_real:
            result = op[-1].value.realval + (double)op->value.intval;
#ifdef HAVE_ISINF
            if (isinf(result))
                return_error(gs_error_undefinedresult);
#endif
#ifdef HAVE_ISNAN
            if (isnan(result))
                return_error(gs_error_undefinedresult);
#endif
            op[-1].value.realval = result;
            break;
        case t_integer: {
            if (sizeof(ps_int) != 4 && gs_currentcpsimode(imemory)) {
                ps_int32 int1 = (ps_int32)op[-1].value.intval;
                ps_int32 int2 = (ps_int32)op->value.intval;

                if (((int1 += int2) ^ int2) < 0 &&
                    ((int1 - int2) ^ int2) >= 0
                    ) {                     /* Overflow, convert to real */
                    make_real(op - 1, (double)(int1 - int2) + int2);
                }
                else {
                    op[-1].value.intval = (ps_int)int1;
                }
            }
            else {
                ps_int int2 = op->value.intval;

                if (((op[-1].value.intval += int2) ^ int2) < 0 &&
                    ((op[-1].value.intval - int2) ^ int2) >= 0
                    ) {                     /* Overflow, convert to real */
                    make_real(op - 1, (double)(op[-1].value.intval - int2) + int2);
                }
            }
        }
        }
    }
    return 0;
}
int
zadd(i_ctx_t *i_ctx_p)
{
    int code = zop_add(i_ctx_p);

    if (code == 0) {
        pop(1);
    }
    return code;
}

/* <num1> <num2> div <real_quotient> */
int
zdiv(i_ctx_t *i_ctx_p)
{
    os_ptr op = osp;
    os_ptr op1 = op - 1;
    float result;

    check_op(2);
    /* We can't use the non_int_cases macro, */
    /* because we have to check explicitly for op == 0. */
    switch (r_type(op)) {
        default:
            return_op_typecheck(op);
        case t_real:
            if (op->value.realval == 0)
                return_error(gs_error_undefinedresult);
            switch (r_type(op1)) {
                default:
                    return_op_typecheck(op1);
                case t_real:
                    result = op1->value.realval / op->value.realval;
#ifdef HAVE_ISINF
                    if (isinf(result))
                        return_error(gs_error_undefinedresult);
#endif
#ifdef HAVE_ISNAN
                    if (isnan(result))
                        return_error(gs_error_undefinedresult);
#endif
                    op1->value.realval = result;
                    break;
                case t_integer:
                    result = (double)op1->value.intval / op->value.realval;
#ifdef HAVE_ISINF
                    if (isinf(result))
                        return_error(gs_error_undefinedresult);
#endif
#ifdef HAVE_ISNAN
                    if (isnan(result))
                        return_error(gs_error_undefinedresult);
#endif
                    make_real(op1, result);
            }
            break;
        case t_integer:
            if (op->value.intval == 0)
                return_error(gs_error_undefinedresult);
            switch (r_type(op1)) {
                default:
                    return_op_typecheck(op1);
                case t_real:
                    result = op1->value.realval / (double)op->value.intval;
#ifdef HAVE_ISINF
                    if (isinf(result))
                        return_error(gs_error_undefinedresult);
#endif
#ifdef HAVE_ISNAN
                    if (isnan(result))
                        return_error(gs_error_undefinedresult);
#endif
                    op1->value.realval = result;
                    break;
                case t_integer:
                    result = (double)op1->value.intval / (double)op->value.intval;
#ifdef HAVE_ISINF
                    if (isinf(result))
                        return_error(gs_error_undefinedresult);
#endif
#ifdef HAVE_ISNAN
                    if (isnan(result))
                        return_error(gs_error_undefinedresult);
#endif
                    make_real(op1, result);
            }
    }
    pop(1);
    return 0;
}

/*
To detect 64bit x 64bit multiplication overflowing, consider
breaking the numbers down into 32bit chunks.

  abc = (a<<64) + (b<<32) + c
      (where a is 0 or -1, and b and c are 32bit unsigned.

Similarly:

  def = (d<<64) + (b<<32) + f

Then:

  abc.def = ((a<<64) + (b<<32) + c) * ((d<<64) + (e<<32) + f)
          = (a<<64).def + (d<<64).abc + (b<<32).(e<<32) +
            (b<<32).f + (e<<32).c + cf
          = (a.def + d.abc + b.e)<<64 + (b.f + e.c)<<32 + cf

*/

static int mul_64_64_overflowcheck(int64_t abc, int64_t def, int64_t *res)
{
  uint32_t b = (abc>>32);
  uint32_t c = (uint32_t)abc;
  uint32_t e = (def>>32);
  uint32_t f = (uint32_t)def;
  uint64_t low, mid, high, bf, ec;

  /* Low contribution */
  low = (uint64_t)c * (uint64_t)f;
  /* Mid contributions */
  bf = (uint64_t)b * (uint64_t)f;
  ec = (uint64_t)e * (uint64_t)c;
  /* Top contribution */
  high = (uint64_t)b * (uint64_t)e;
  if (abc < 0)
      high -= def;
  if (def < 0)
      high -= abc;
  /* How do we check for carries from 64bit unsigned adds?
   *  x + y >= (1<<64) == x >= (1<<64) - y
   *                   == x >  (1<<64) - y - 1
   * if we consider just 64bits, this is:
   * x > NOT y
   */
  if (bf > ~ec)
      high += ((uint64_t)1)<<32;
  mid = bf + ec;
  if (low > ~(mid<<32))
      high += 1;
  high += (mid>>32);
  low += (mid<<32);

  *res = low;

  return (int64_t)low < 0 ? high != -1 : high != 0;
}

/* <num1> <num2> mul <product> */
int
zmul(i_ctx_t *i_ctx_p)
{
    os_ptr op = osp;
    float result;

    switch (r_type(op)) {
    default:
        return_op_typecheck(op);
    case t_real:
        switch (r_type(op - 1)) {
        default:
            return_op_typecheck(op - 1);
        case t_real:
            result = op[-1].value.realval * op->value.realval;
#ifdef HAVE_ISINF
            if (isinf(result))
                return_error(gs_error_undefinedresult);
#endif
#ifdef HAVE_ISNAN
            if (isnan(result))
                return_error(gs_error_undefinedresult);
#endif
            op[-1].value.realval = result;
            break;
        case t_integer:
            result = (double)op[-1].value.intval * op->value.realval;
            make_real(op - 1, result);
        }
        break;
    case t_integer:
        switch (r_type(op - 1)) {
        default:
            return_op_typecheck(op - 1);
        case t_real:
            result = op[-1].value.realval * (double)op->value.intval;
#ifdef HAVE_ISINF
            if (isinf(result))
                return_error(gs_error_undefinedresult);
#endif
#ifdef HAVE_ISNAN
            if (isnan(result))
                return_error(gs_error_undefinedresult);
#endif
            op[-1].value.realval = result;
            break;
        case t_integer: {
            if (sizeof(ps_int) != 4 && gs_currentcpsimode(imemory)) {
                double ab = (double)op[-1].value.intval * op->value.intval;
                if (ab > (double)MAX_PS_INT32)       /* (double)0x7fffffff */
                    make_real(op - 1, ab);
                else if (ab < (double)MIN_PS_INT32) /* (double)(int)0x80000000 */
                    make_real(op - 1, ab);
                else
                    op[-1].value.intval = (ps_int)ab;
            }
            else {
                int64_t result;
                if (mul_64_64_overflowcheck(op[-1].value.intval, op->value.intval, &result)) {
                    double ab = (double)op[-1].value.intval * op->value.intval;
                    make_real(op - 1, ab);
                } else {
                    op[-1].value.intval = result;
                }
            }
        }
        }
    }
    pop(1);
    return 0;
}

/* <num1> <num2> sub <difference> */
/* We make this into a separate procedure because */
/* the interpreter will almost always call it directly. */
int
zop_sub(i_ctx_t *i_ctx_p)
{
    register os_ptr op = osp;

    check_op(2);
    switch (r_type(op)) {
    default:
        return_op_typecheck(op);
    case t_real:
        switch (r_type(op - 1)) {
        default:
            return_op_typecheck(op - 1);
        case t_real:
            op[-1].value.realval -= op->value.realval;
            break;
        case t_integer:
            make_real(op - 1, (double)op[-1].value.intval - op->value.realval);
        }
        break;
    case t_integer:
        switch (r_type(op - 1)) {
        default:
            return_op_typecheck(op - 1);
        case t_real:
            op[-1].value.realval -= (double)op->value.intval;
            break;
        case t_integer: {
            if (sizeof(ps_int) != 4 && gs_currentcpsimode(imemory)) {
                ps_int32 int1 = (ps_int)op[-1].value.intval;
                ps_int32 int2 = (ps_int)op->value.intval;
                ps_int32 int3;

                if ((int1 ^ (int3 = int1 - int2)) < 0 &&
                    (int1 ^ int2) < 0
                    ) {                     /* Overflow, convert to real */
                    make_real(op - 1, (float)int1 - op->value.intval);
                }
                else {
                    op[-1].value.intval = (ps_int)int3;
                }
            }
            else {
                ps_int int1 = op[-1].value.intval;

                if ((int1 ^ (op[-1].value.intval = int1 - op->value.intval)) < 0 &&
                    (int1 ^ op->value.intval) < 0
                    ) {                     /* Overflow, convert to real */
                    make_real(op - 1, (float)int1 - op->value.intval);
                }
            }
        }
        }
    }
    return 0;
}
int
zsub(i_ctx_t *i_ctx_p)
{
    int code = zop_sub(i_ctx_p);

    if (code == 0) {
        pop(1);
    }
    return code;
}

/* <num1> <num2> idiv <int_quotient> */
int
zidiv(i_ctx_t *i_ctx_p)
{
    os_ptr op = osp;

    check_op(2);
    check_type(*op, t_integer);
    check_type(op[-1], t_integer);
    if (sizeof(ps_int) && gs_currentcpsimode(imemory)) {
        int tmpval;
        if ((op->value.intval == 0) || (op[-1].value.intval == (ps_int)MIN_PS_INT32 && op->value.intval == -1)) {
            /* Anomalous boundary case: -MININT / -1, fail. */
            return_error(gs_error_undefinedresult);
        }
        tmpval = (int)op[-1].value.intval / op->value.intval;
        op[-1].value.intval = (int64_t)tmpval;
    }
    else {
        if ((op->value.intval == 0) || (op[-1].value.intval == MIN_PS_INT && op->value.intval == -1)) {
            /* Anomalous boundary case: -MININT / -1, fail. */
            return_error(gs_error_undefinedresult);
        }
        op[-1].value.intval /= op->value.intval;
    }
    pop(1);
    return 0;
}

/* <int1> <int2> mod <remainder> */
int
zmod(i_ctx_t *i_ctx_p)
{
    os_ptr op = osp;

    check_op(2);
    check_type(*op, t_integer);
    check_type(op[-1], t_integer);
    if (op->value.intval == 0 || op[-1].value.intval == MIN_PS_INT)
        return_error(gs_error_undefinedresult);
    op[-1].value.intval %= op->value.intval;
    pop(1);
    return 0;
}

/* <num1> neg <num2> */
int
zneg(i_ctx_t *i_ctx_p)
{
    os_ptr op = osp;

    check_op(1);
    switch (r_type(op)) {
        default:
            return_op_typecheck(op);
        case t_real:
            op->value.realval = -op->value.realval;
            break;
        case t_integer:
            if (sizeof(ps_int) != 32 && gs_currentcpsimode(imemory)) {
                if (((unsigned int)op->value.intval) == MIN_PS_INT32)
                    make_real(op, -(float)(ps_uint32)MIN_PS_INT32);
                else
                    op->value.intval = -op->value.intval;
            }
            else {
                if (op->value.intval == MIN_PS_INT)
                    make_real(op, -(float)MIN_PS_INT);
                else
                    op->value.intval = -op->value.intval;
            }
    }
    return 0;
}

/* <num1> abs <num2> */
int
zabs(i_ctx_t *i_ctx_p)
{
    os_ptr op = osp;

    check_op(1);
    switch (r_type(op)) {
        default:
            return_op_typecheck(op);
        case t_real:
            if (op->value.realval >= 0)
                return 0;
            break;
        case t_integer:
            if (op->value.intval >= 0)
                return 0;
            break;
    }
    return zneg(i_ctx_p);
}

/* <num1> ceiling <num2> */
int
zceiling(i_ctx_t *i_ctx_p)
{
    os_ptr op = osp;

    check_op(1);
    switch (r_type(op)) {
        default:
            return_op_typecheck(op);
        case t_real:
            op->value.realval = ceil(op->value.realval);
        case t_integer:;
    }
    return 0;
}

/* <num1> floor <num2> */
int
zfloor(i_ctx_t *i_ctx_p)
{
    os_ptr op = osp;

    check_op(1);
    switch (r_type(op)) {
        default:
            return_op_typecheck(op);
        case t_real:
            op->value.realval = floor(op->value.realval);
        case t_integer:;
    }
    return 0;
}

/* <num1> round <num2> */
int
zround(i_ctx_t *i_ctx_p)
{
    os_ptr op = osp;

    check_op(1);
    switch (r_type(op)) {
        default:
            return_op_typecheck(op);
        case t_real:
            op->value.realval = floor(op->value.realval + 0.5);
        case t_integer:;
    }
    return 0;
}

/* <num1> truncate <num2> */
int
ztruncate(i_ctx_t *i_ctx_p)
{
    os_ptr op = osp;

    check_op(1);
    switch (r_type(op)) {
        default:
            return_op_typecheck(op);
        case t_real:
            op->value.realval =
                (op->value.realval < 0.0 ?
                 ceil(op->value.realval) :
                 floor(op->value.realval));
        case t_integer:;
    }
    return 0;
}

/* Non-standard operators */

/* <int1> <int2> .bitadd <sum> */
static int
zbitadd(i_ctx_t *i_ctx_p)
{
    os_ptr op = osp;

    check_op(2);
    check_type(*op, t_integer);
    check_type(op[-1], t_integer);
    op[-1].value.intval += op->value.intval;
    pop(1);
    return 0;
}

/* ------ Initialization table ------ */

const op_def zarith_op_defs[] =
{
    {"1abs", zabs},
    {"2add", zadd},
    {"2.bitadd", zbitadd},
    {"1ceiling", zceiling},
    {"2div", zdiv},
    {"2idiv", zidiv},
    {"1floor", zfloor},
    {"2mod", zmod},
    {"2mul", zmul},
    {"1neg", zneg},
    {"1round", zround},
    {"2sub", zsub},
    {"1truncate", ztruncate},
    op_def_end(0)
};

Coverage Report

Created: 2025-06-10 06:56

Line	Count	Source (jump to first uncovered line)
1		/* Copyright (C) 2001-2023 Artifex Software, Inc.
2		All Rights Reserved.
3
4		This software is provided AS-IS with no warranty, either express or
5		implied.
6
7		This software is distributed under license and may not be copied,
8		modified or distributed except as expressly authorized under the terms
9		of the license contained in the file LICENSE in this distribution.
10
11		Refer to licensing information at http://www.artifex.com or contact
12		Artifex Software, Inc., 39 Mesa Street, Suite 108A, San Francisco,
13		CA 94129, USA, for further information.
14		*/
15
16
17		/* Arithmetic operators */
18		#include "math_.h"
19		#include "ghost.h"
20		#include "oper.h"
21		#include "store.h"
22		#include "gsstate.h"
23
24		/*
25		* Many of the procedures in this file are public only so they can be
26		* called from the FunctionType 4 interpreter (zfunc4.c).
27		*/
28
29		static int mul_64_64_overflowcheck(int64_t abc, int64_t def, int64_t *res);
30
31		/* <num1> <num2> add <sum> */
32		/* We make this into a separate procedure because */
33		/* the interpreter will almost always call it directly. */
34		int
35		zop_add(i_ctx_t *i_ctx_p)
36	5.82M	{
37	5.82M	register os_ptr op = osp;
38	5.82M	float result;
39
40	5.82M	check_op(2);
41	5.82M	switch (r_type(op)) {
42	0	default:
43	0	return_op_typecheck(op);
44	373k	case t_real:
45	373k	switch (r_type(op - 1)) {
46	0	default:
47	0	return_op_typecheck(op - 1);
48	186k	case t_real:
49	186k	result = op[-1].value.realval + op->value.realval;
50	186k	#ifdef HAVE_ISINF
51	186k	if (isinf(result))
52	0	return_error(gs_error_undefinedresult);
53	186k	#endif
54	186k	#ifdef HAVE_ISNAN
55	186k	if (isnan(result))
56	0	return_error(gs_error_undefinedresult);
57	186k	#endif
58	186k	op[-1].value.realval = result;
59	186k	break;
60	186k	case t_integer:
61	186k	make_real(op - 1, (double)op[-1].value.intval + op->value.realval);
62	373k	}
63	373k	break;
64	5.45M	case t_integer:
65	5.45M	switch (r_type(op - 1)) {
66	0	default:
67	0	return_op_typecheck(op - 1);
68	373k	case t_real:
69	373k	result = op[-1].value.realval + (double)op->value.intval;
70	373k	#ifdef HAVE_ISINF
71	373k	if (isinf(result))
72	0	return_error(gs_error_undefinedresult);
73	373k	#endif
74	373k	#ifdef HAVE_ISNAN
75	373k	if (isnan(result))
76	0	return_error(gs_error_undefinedresult);
77	373k	#endif
78	373k	op[-1].value.realval = result;
79	373k	break;
80	5.07M	case t_integer: {
81	5.07M	if (sizeof(ps_int) != 4 && gs_currentcpsimode(imemory)) {
82	0	ps_int32 int1 = (ps_int32)op[-1].value.intval;
83	0	ps_int32 int2 = (ps_int32)op->value.intval;
84
85	0	if (((int1 += int2) ^ int2) < 0 &&
86	0	((int1 - int2) ^ int2) >= 0
87	0	) { /* Overflow, convert to real */
88	0	make_real(op - 1, (double)(int1 - int2) + int2);
89	0	}
90	0	else {
91	0	op[-1].value.intval = (ps_int)int1;
92	0	}
93	0	}
94	5.07M	else {
95	5.07M	ps_int int2 = op->value.intval;
96
97	5.07M	if (((op[-1].value.intval += int2) ^ int2) < 0 &&
98	5.07M	((op[-1].value.intval - int2) ^ int2) >= 0
99	5.07M	) { /* Overflow, convert to real */
100	0	make_real(op - 1, (double)(op[-1].value.intval - int2) + int2);
101	0	}
102	5.07M	}
103	5.07M	}
104	5.45M	}
105	5.82M	}
106	5.82M	return 0;
107	5.82M	}
108		int
109		zadd(i_ctx_t *i_ctx_p)
110	0	{
111	0	int code = zop_add(i_ctx_p);
112
113	0	if (code == 0) {
114	0	pop(1);
115	0	}
116	0	return code;
117	0	}
118
119		/* <num1> <num2> div <real_quotient> */
120		int
121		zdiv(i_ctx_t *i_ctx_p)
122	215k	{
123	215k	os_ptr op = osp;
124	215k	os_ptr op1 = op - 1;
125	215k	float result;
126
127	215k	check_op(2);
128		/* We can't use the non_int_cases macro, */
129		/* because we have to check explicitly for op == 0. */
130	215k	switch (r_type(op)) {
131	0	default:
132	0	return_op_typecheck(op);
133	10.3k	case t_real:
134	10.3k	if (op->value.realval == 0)
135	0	return_error(gs_error_undefinedresult);
136	10.3k	switch (r_type(op1)) {
137	0	default:
138	0	return_op_typecheck(op1);
139	10.3k	case t_real:
140	10.3k	result = op1->value.realval / op->value.realval;
141	10.3k	#ifdef HAVE_ISINF
142	10.3k	if (isinf(result))
143	0	return_error(gs_error_undefinedresult);
144	10.3k	#endif
145	10.3k	#ifdef HAVE_ISNAN
146	10.3k	if (isnan(result))
147	0	return_error(gs_error_undefinedresult);
148	10.3k	#endif
149	10.3k	op1->value.realval = result;
150	10.3k	break;
151	2	case t_integer:
152	2	result = (double)op1->value.intval / op->value.realval;
153	2	#ifdef HAVE_ISINF
154	2	if (isinf(result))
155	0	return_error(gs_error_undefinedresult);
156	2	#endif
157	2	#ifdef HAVE_ISNAN
158	2	if (isnan(result))
159	0	return_error(gs_error_undefinedresult);
160	2	#endif
161	10.3k	make_real(op1, result);
162	10.3k	}
163	10.3k	break;
164	205k	case t_integer:
165	205k	if (op->value.intval == 0)
166	0	return_error(gs_error_undefinedresult);
167	205k	switch (r_type(op1)) {
168	0	default:
169	0	return_op_typecheck(op1);
170	204k	case t_real:
171	204k	result = op1->value.realval / (double)op->value.intval;
172	204k	#ifdef HAVE_ISINF
173	204k	if (isinf(result))
174	0	return_error(gs_error_undefinedresult);
175	204k	#endif
176	204k	#ifdef HAVE_ISNAN
177	204k	if (isnan(result))
178	0	return_error(gs_error_undefinedresult);
179	204k	#endif
180	204k	op1->value.realval = result;
181	204k	break;
182	1.39k	case t_integer:
183	1.39k	result = (double)op1->value.intval / (double)op->value.intval;
184	1.39k	#ifdef HAVE_ISINF
185	1.39k	if (isinf(result))
186	0	return_error(gs_error_undefinedresult);
187	1.39k	#endif
188	1.39k	#ifdef HAVE_ISNAN
189	1.39k	if (isnan(result))
190	0	return_error(gs_error_undefinedresult);
191	1.39k	#endif
192	205k	make_real(op1, result);
193	205k	}
194	215k	}
195	215k	pop(1);
196	215k	return 0;
197	215k	}
198
199		/*
200		To detect 64bit x 64bit multiplication overflowing, consider
201		breaking the numbers down into 32bit chunks.
202
203		abc = (a<<64) + (b<<32) + c
204		(where a is 0 or -1, and b and c are 32bit unsigned.
205
206		Similarly:
207
208		def = (d<<64) + (b<<32) + f
209
210		Then:
211
212		abc.def = ((a<<64) + (b<<32) + c) * ((d<<64) + (e<<32) + f)
213		= (a<<64).def + (d<<64).abc + (b<<32).(e<<32) +
214		(b<<32).f + (e<<32).c + cf
215		= (a.def + d.abc + b.e)<<64 + (b.f + e.c)<<32 + cf
216
217		*/
218
219		static int mul_64_64_overflowcheck(int64_t abc, int64_t def, int64_t *res)
220	128k	{
221	128k	uint32_t b = (abc>>32);
222	128k	uint32_t c = (uint32_t)abc;
223	128k	uint32_t e = (def>>32);
224	128k	uint32_t f = (uint32_t)def;
225	128k	uint64_t low, mid, high, bf, ec;
226
227		/* Low contribution */
228	128k	low = (uint64_t)c * (uint64_t)f;
229		/* Mid contributions */
230	128k	bf = (uint64_t)b * (uint64_t)f;
231	128k	ec = (uint64_t)e * (uint64_t)c;
232		/* Top contribution */
233	128k	high = (uint64_t)b * (uint64_t)e;
234	128k	if (abc < 0)
235	0	high -= def;
236	128k	if (def < 0)
237	0	high -= abc;
238		/* How do we check for carries from 64bit unsigned adds?
239		* x + y >= (1<<64) == x >= (1<<64) - y
240		* == x > (1<<64) - y - 1
241		* if we consider just 64bits, this is:
242		* x > NOT y
243		*/
244	128k	if (bf > ~ec)
245	0	high += ((uint64_t)1)<<32;
246	128k	mid = bf + ec;
247	128k	if (low > ~(mid<<32))
248	0	high += 1;
249	128k	high += (mid>>32);
250	128k	low += (mid<<32);
251
252	128k	*res = low;
253
254	128k	return (int64_t)low < 0 ? high != -1 : high != 0;
255	128k	}
256
257		/* <num1> <num2> mul <product> */
258		int
259		zmul(i_ctx_t *i_ctx_p)
260	894k	{
261	894k	os_ptr op = osp;
262	894k	float result;
263
264	894k	switch (r_type(op)) {
265	0	default:
266	0	return_op_typecheck(op);
267	384k	case t_real:
268	384k	switch (r_type(op - 1)) {
269	0	default:
270	0	return_op_typecheck(op - 1);
271	373k	case t_real:
272	373k	result = op[-1].value.realval * op->value.realval;
273	373k	#ifdef HAVE_ISINF
274	373k	if (isinf(result))
275	0	return_error(gs_error_undefinedresult);
276	373k	#endif
277	373k	#ifdef HAVE_ISNAN
278	373k	if (isnan(result))
279	0	return_error(gs_error_undefinedresult);
280	373k	#endif
281	373k	op[-1].value.realval = result;
282	373k	break;
283	10.3k	case t_integer:
284	10.3k	result = (double)op[-1].value.intval * op->value.realval;
285	10.3k	make_real(op - 1, result);
286	384k	}
287	384k	break;
288	510k	case t_integer:
289	510k	switch (r_type(op - 1)) {
290	0	default:
291	0	return_op_typecheck(op - 1);
292	382k	case t_real:
293	382k	result = op[-1].value.realval * (double)op->value.intval;
294	382k	#ifdef HAVE_ISINF
295	382k	if (isinf(result))
296	0	return_error(gs_error_undefinedresult);
297	382k	#endif
298	382k	#ifdef HAVE_ISNAN
299	382k	if (isnan(result))
300	0	return_error(gs_error_undefinedresult);
301	382k	#endif
302	382k	op[-1].value.realval = result;
303	382k	break;
304	128k	case t_integer: {
305	128k	if (sizeof(ps_int) != 4 && gs_currentcpsimode(imemory)) {
306	0	double ab = (double)op[-1].value.intval * op->value.intval;
307	0	if (ab > (double)MAX_PS_INT32) /* (double)0x7fffffff */
308	0	make_real(op - 1, ab);
309	0	else if (ab < (double)MIN_PS_INT32) /* (double)(int)0x80000000 */
310	0	make_real(op - 1, ab);
311	0	else
312	0	op[-1].value.intval = (ps_int)ab;
313	0	}
314	128k	else {
315	128k	int64_t result;
316	128k	if (mul_64_64_overflowcheck(op[-1].value.intval, op->value.intval, &result)) {
317	0	double ab = (double)op[-1].value.intval * op->value.intval;
318	0	make_real(op - 1, ab);
319	128k	} else {
320	128k	op[-1].value.intval = result;
321	128k	}
322	128k	}
323	128k	}
324	510k	}
325	894k	}
326	894k	pop(1);
327	894k	return 0;
328	894k	}
329
330		/* <num1> <num2> sub <difference> */
331		/* We make this into a separate procedure because */
332		/* the interpreter will almost always call it directly. */
333		int
334		zop_sub(i_ctx_t *i_ctx_p)
335	1.00M	{
336	1.00M	register os_ptr op = osp;
337
338	1.00M	check_op(2);
339	1.00M	switch (r_type(op)) {
340	0	default:
341	0	return_op_typecheck(op);
342	190k	case t_real:
343	190k	switch (r_type(op - 1)) {
344	0	default:
345	0	return_op_typecheck(op - 1);
346	3.35k	case t_real:
347	3.35k	op[-1].value.realval -= op->value.realval;
348	3.35k	break;
349	186k	case t_integer:
350	186k	make_real(op - 1, (double)op[-1].value.intval - op->value.realval);
351	190k	}
352	190k	break;
353	810k	case t_integer:
354	810k	switch (r_type(op - 1)) {
355	0	default:
356	0	return_op_typecheck(op - 1);
357	1.64k	case t_real:
358	1.64k	op[-1].value.realval -= (double)op->value.intval;
359	1.64k	break;
360	809k	case t_integer: {
361	809k	if (sizeof(ps_int) != 4 && gs_currentcpsimode(imemory)) {
362	0	ps_int32 int1 = (ps_int)op[-1].value.intval;
363	0	ps_int32 int2 = (ps_int)op->value.intval;
364	0	ps_int32 int3;
365
366	0	if ((int1 ^ (int3 = int1 - int2)) < 0 &&
367	0	(int1 ^ int2) < 0
368	0	) { /* Overflow, convert to real */
369	0	make_real(op - 1, (float)int1 - op->value.intval);
370	0	}
371	0	else {
372	0	op[-1].value.intval = (ps_int)int3;
373	0	}
374	0	}
375	809k	else {
376	809k	ps_int int1 = op[-1].value.intval;
377
378	809k	if ((int1 ^ (op[-1].value.intval = int1 - op->value.intval)) < 0 &&
379	809k	(int1 ^ op->value.intval) < 0
380	809k	) { /* Overflow, convert to real */
381	0	make_real(op - 1, (float)int1 - op->value.intval);
382	0	}
383	809k	}
384	809k	}
385	810k	}
386	1.00M	}
387	1.00M	return 0;
388	1.00M	}
389		int
390		zsub(i_ctx_t *i_ctx_p)
391	0	{
392	0	int code = zop_sub(i_ctx_p);
393
394	0	if (code == 0) {
395	0	pop(1);
396	0	}
397	0	return code;
398	0	}
399
400		/* <num1> <num2> idiv <int_quotient> */
401		int
402		zidiv(i_ctx_t *i_ctx_p)
403	479k	{
404	479k	os_ptr op = osp;
405
406	479k	check_op(2);
407	479k	check_type(*op, t_integer);
408	479k	check_type(op[-1], t_integer);
409	479k	if (sizeof(ps_int) && gs_currentcpsimode(imemory)) {
410	0	int tmpval;
411	0	if ((op->value.intval == 0) \|\| (op[-1].value.intval == (ps_int)MIN_PS_INT32 && op->value.intval == -1)) {
412		/* Anomalous boundary case: -MININT / -1, fail. */
413	0	return_error(gs_error_undefinedresult);
414	0	}
415	0	tmpval = (int)op[-1].value.intval / op->value.intval;
416	0	op[-1].value.intval = (int64_t)tmpval;
417	0	}
418	479k	else {
419	479k	if ((op->value.intval == 0) \|\| (op[-1].value.intval == MIN_PS_INT && op->value.intval == -1)) {
420		/* Anomalous boundary case: -MININT / -1, fail. */
421	0	return_error(gs_error_undefinedresult);
422	0	}
423	479k	op[-1].value.intval /= op->value.intval;
424	479k	}
425	479k	pop(1);
426	479k	return 0;
427	479k	}
428
429		/* <int1> <int2> mod <remainder> */
430		int
431		zmod(i_ctx_t *i_ctx_p)
432	3	{
433	3	os_ptr op = osp;
434
435	3	check_op(2);
436	3	check_type(*op, t_integer);
437	3	check_type(op[-1], t_integer);
438	3	if (op->value.intval == 0 \|\| op[-1].value.intval == MIN_PS_INT)
439	0	return_error(gs_error_undefinedresult);
440	3	op[-1].value.intval %= op->value.intval;
441	3	pop(1);
442	3	return 0;
443	3	}
444
445		/* <num1> neg <num2> */
446		int
447		zneg(i_ctx_t *i_ctx_p)
448	19.0k	{
449	19.0k	os_ptr op = osp;
450
451	19.0k	check_op(1);
452	19.0k	switch (r_type(op)) {
453	0	default:
454	0	return_op_typecheck(op);
455	13.8k	case t_real:
456	13.8k	op->value.realval = -op->value.realval;
457	13.8k	break;
458	5.25k	case t_integer:
459	5.25k	if (sizeof(ps_int) != 32 && gs_currentcpsimode(imemory)) {
460	0	if (((unsigned int)op->value.intval) == MIN_PS_INT32)
461	0	make_real(op, -(float)(ps_uint32)MIN_PS_INT32);
462	0	else
463	0	op->value.intval = -op->value.intval;
464	0	}
465	5.25k	else {
466	5.25k	if (op->value.intval == MIN_PS_INT)
467	5.25k	make_real(op, -(float)MIN_PS_INT);
468	5.25k	else
469	5.25k	op->value.intval = -op->value.intval;
470	5.25k	}
471	19.0k	}
472	19.0k	return 0;
473	19.0k	}
474
475		/* <num1> abs <num2> */
476		int
477		zabs(i_ctx_t *i_ctx_p)
478	24.3k	{
479	24.3k	os_ptr op = osp;
480
481	24.3k	check_op(1);
482	24.3k	switch (r_type(op)) {
483	0	default:
484	0	return_op_typecheck(op);
485	24.3k	case t_real:
486	24.3k	if (op->value.realval >= 0)
487	12.1k	return 0;
488	12.1k	break;
489	12.1k	case t_integer:
490	0	if (op->value.intval >= 0)
491	0	return 0;
492	0	break;
493	24.3k	}
494	12.1k	return zneg(i_ctx_p);
495	24.3k	}
496
497		/* <num1> ceiling <num2> */
498		int
499		zceiling(i_ctx_t *i_ctx_p)
500	0	{
501	0	os_ptr op = osp;
502
503	0	check_op(1);
504	0	switch (r_type(op)) {
505	0	default:
506	0	return_op_typecheck(op);
507	0	case t_real:
508	0	op->value.realval = ceil(op->value.realval);
509	0	case t_integer:;
510	0	}
511	0	return 0;
512	0	}
513
514		/* <num1> floor <num2> */
515		int
516		zfloor(i_ctx_t *i_ctx_p)
517	0	{
518	0	os_ptr op = osp;
519
520	0	check_op(1);
521	0	switch (r_type(op)) {
522	0	default:
523	0	return_op_typecheck(op);
524	0	case t_real:
525	0	op->value.realval = floor(op->value.realval);
526	0	case t_integer:;
527	0	}
528	0	return 0;
529	0	}
530
531		/* <num1> round <num2> */
532		int
533		zround(i_ctx_t *i_ctx_p)
534	3	{
535	3	os_ptr op = osp;
536
537	3	check_op(1);
538	3	switch (r_type(op)) {
539	0	default:
540	0	return_op_typecheck(op);
541	3	case t_real:
542	3	op->value.realval = floor(op->value.realval + 0.5);
543	3	case t_integer:;
544	3	}
545	3	return 0;
546	3	}
547
548		/* <num1> truncate <num2> */
549		int
550		ztruncate(i_ctx_t *i_ctx_p)
551	1	{
552	1	os_ptr op = osp;
553
554	1	check_op(1);
555	1	switch (r_type(op)) {
556	0	default:
557	0	return_op_typecheck(op);
558	1	case t_real:
559	1	op->value.realval =
560	1	(op->value.realval < 0.0 ?
561	0	ceil(op->value.realval) :
562	1	floor(op->value.realval));
563	1	case t_integer:;
564	1	}
565	1	return 0;
566	1	}
567
568		/* Non-standard operators */
569
570		/* <int1> <int2> .bitadd <sum> */
571		static int
572		zbitadd(i_ctx_t *i_ctx_p)
573	0	{
574	0	os_ptr op = osp;
575
576	0	check_op(2);
577	0	check_type(*op, t_integer);
578	0	check_type(op[-1], t_integer);
579	0	op[-1].value.intval += op->value.intval;
580	0	pop(1);
581	0	return 0;
582	0	}
583
584		/* ------ Initialization table ------ */
585
586		const op_def zarith_op_defs[] =
587		{
588		{"1abs", zabs},
589		{"2add", zadd},
590		{"2.bitadd", zbitadd},
591		{"1ceiling", zceiling},
592		{"2div", zdiv},
593		{"2idiv", zidiv},
594		{"1floor", zfloor},
595		{"2mod", zmod},
596		{"2mul", zmul},
597		{"1neg", zneg},
598		{"1round", zround},
599		{"2sub", zsub},
600		{"1truncate", ztruncate},
601		op_def_end(0)
602		};