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/* Copyright (c) 2000 TXT DataKonsult Ab & Monty Program Ab
Copyright (c) 2009-2011, Monty Program Ab
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must the following disclaimer in
the documentation and/or other materials provided with the
distribution.
THIS SOFTWARE IS PROVIDED BY <COPYRIGHT HOLDER> ``AS IS'' AND ANY
EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> OR
CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF
USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
SUCH DAMAGE.
*/
/*
str2int(src, radix, lower, upper, &val)
converts the string pointed to by src to an integer and stores it in
val. It skips leading spaces and tabs (but not newlines, formfeeds,
backspaces), then it accepts an optional sign and a sequence of digits
in the specified radix. The result should satisfy lower <= *val <= upper.
The result is a pointer to the first character after the number;
trailing spaces will NOT be skipped.
If an error is detected, the result will be NullS, the value put
in val will be 0, and errno will be set to
EDOM if there are no digits
ERANGE if the result would overflow or otherwise fail to lie
within the specified bounds.
Check that the bounds are right for your machine.
This looks amazingly complicated for what you probably thought was an
easy task. Coping with integer overflow and the asymmetric range of
twos complement machines is anything but easy.
So that users of atoi and atol can check whether an error occured,
I have taken a wholly unprecedented step: errno is CLEARED if this
call has no problems.
*/
#include "strings_def.h"
#include <m_ctype.h>
#include "my_sys.h" /* defines errno */
#include <errno.h>
#define char_val(X) (X >= '0' && X <= '9' ? X-'0' :\
X >= 'A' && X <= 'Z' ? X-'A'+10 :\
X >= 'a' && X <= 'z' ? X-'a'+10 :\
'\177')
char *str2int(register const char *src, register int radix, long int lower,
long int upper, long int *val)
{
int sign; /* is number negative (+1) or positive (-1) */
int n; /* number of digits yet to be converted */
long limit; /* "largest" possible valid input */
long scale; /* the amount to multiply next digit by */
long sofar; /* the running value */
register int d; /* (negative of) next digit */
char *start;
int digits[32]; /* Room for numbers */
/* Make sure *val is sensible in case of error */
*val = 0;
/* Check that the radix is in the range 2..36 */
#ifndef DBUG_OFF
if (radix < 2 || radix > 36) {
errno=EDOM;
return NullS;
}
#endif
/* The basic problem is: how do we handle the conversion of
a number without resorting to machine-specific code to
check for overflow? Obviously, we have to ensure that
no calculation can overflow. We are guaranteed that the
"lower" and "upper" arguments are valid machine integers.
On sign-and-magnitude, twos-complement, and ones-complement
machines all, if +|n| is representable, so is -|n|, but on
twos complement machines the converse is not true. So the
"maximum" representable number has a negative representative.
Limit is set to min(-|lower|,-|upper|); this is the "largest"
number we are concerned with. */
/* Calculate Limit using Scale as a scratch variable */
if ((limit = lower) > 0) limit = -limit;
if ((scale = upper) > 0) scale = -scale;
if (scale < limit) limit = scale;
/* Skip leading spaces and check for a sign.
Note: because on a 2s complement machine MinLong is a valid
integer but |MinLong| is not, we have to keep the current
converted value (and the scale!) as *negative* numbers,
so the sign is the opposite of what you might expect.
*/
while (my_isspace(&my_charset_latin1,*src)) src++;
sign = -1;
if (*src == '+') src++; else
if (*src == '-') src++, sign = 1;
/* Skip leading zeros so that we never compute a power of radix
in scale that we won't have a need for. Otherwise sticking
enough 0s in front of a number could cause the multiplication
to overflow when it neededn't.
*/
start=(char*) src;
while (*src == '0') src++;
/* Move over the remaining digits. We have to convert from left
to left in order to avoid overflow. Answer is after last digit.
*/
for (n = 0; (digits[n]=char_val(*src)) < radix && n < 20; n++,src++) ;
/* Check that there is at least one digit */
if (start == src) {
errno=EDOM;
return NullS;
}
/* The invariant we want to maintain is that src is just
to the right of n digits, we've converted k digits to
sofar, scale = -radix**k, and scale < sofar < 0. Now
if the final number is to be within the original
Limit, we must have (to the left)*scale+sofar >= Limit,
or (to the left)*scale >= Limit-sofar, i.e. the digits
to the left of src must form an integer <= (Limit-sofar)/(scale).
In particular, this is true of the next digit. In our
incremental calculation of Limit,
IT IS VITAL that (-|N|)/(-|D|) = |N|/|D|
*/
for (sofar = 0, scale = -1; --n >= 1;)
{
if ((long) -(d=digits[n]) < limit) {
errno=ERANGE;
return NullS;
}
limit = (limit+d)/radix, sofar += d*scale; scale *= radix;
}
if (n == 0)
{
if ((long) -(d=digits[n]) < limit) /* get last digit */
{
errno=ERANGE;
return NullS;
}
sofar+=d*scale;
}
/* Now it might still happen that sofar = -32768 or its equivalent,
so we can't just multiply by the sign and check that the result
is in the range lower..upper. All of this caution is a right
pain in the neck. If only there were a standard routine which
says generate thus and such a signal on integer overflow...
But not enough machines can do it *SIGH*.
*/
if (sign < 0)
{
if (sofar < -LONG_MAX || (sofar= -sofar) > upper)
{
errno=ERANGE;
return NullS;
}
}
else if (sofar < lower)
{
errno=ERANGE;
return NullS;
}
*val = sofar;
errno=0; /* indicate that all went well */
return (char*) src;
}
/* Theese are so slow compared with ordinary, optimized atoi */
#ifdef WANT_OUR_ATOI
int atoi(const char *src)
{
long val;
str2int(src, 10, (long) INT_MIN, (long) INT_MAX, &val);
return (int) val;
}
long atol(const char *src)
{
long val;
str2int(src, 10, LONG_MIN, LONG_MAX, &val);
return val;
}
#endif /* WANT_OUR_ATOI */
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