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0adfceef87
Found by musl's libc-test.
237 lines
7.5 KiB
C++
237 lines
7.5 KiB
C++
/*******************************************************************************
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Copyright(C) Jonas 'Sortie' Termansen 2011, 2013.
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This file is part of the Sortix C Library.
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The Sortix C Library is free software: you can redistribute it and/or modify
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it under the terms of the GNU Lesser General Public License as published by
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the Free Software Foundation, either version 3 of the License, or (at your
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option) any later version.
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The Sortix C Library is distributed in the hope that it will be useful, but
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WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
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or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public
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License for more details.
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You should have received a copy of the GNU Lesser General Public License
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along with the Sortix C Library. If not, see <http://www.gnu.org/licenses/>.
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stdlib/strtol.cpp
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Converts integers represented as strings to binary representation.
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*******************************************************************************/
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#ifndef STRTOL
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#define STRTOL strtol
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#define STRTOL_CHAR char
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#define STRTOL_L(x) x
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#define STRTOL_ISSPACE isspace
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#define STRTOL_INT long
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#define STRTOL_UNSIGNED_INT unsigned long
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#define STRTOL_INT_MIN LONG_MIN
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#define STRTOL_INT_MAX LONG_MAX
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#define STRTOL_INT_IS_UNSIGNED false
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#endif
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#include <assert.h>
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#include <ctype.h>
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#include <errno.h>
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#include <inttypes.h>
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#include <stddef.h>
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#include <stdint.h>
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#include <stdlib.h>
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#include <wchar.h>
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#include <wctype.h>
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// Nasty, nasty hack to get LLONG_* macros.
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#define __STDC_VERSION__ 199901L
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#include <limits.h>
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// Convert a character into a digit.
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static int debase(STRTOL_CHAR c)
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{
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if ( STRTOL_L('0') <= c && c <= STRTOL_L('9') )
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return c - STRTOL_L('0');
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if ( STRTOL_L('a') <= c && c <= STRTOL_L('z') )
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return 10 + c - STRTOL_L('a');
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if ( STRTOL_L('A') <= c && c <= STRTOL_L('Z') )
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return 10 + c - STRTOL_L('A');
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return -1;
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}
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// Determine whether a multiplication of two integers would overflow/underflow.
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// This is easy if we have a larger integer type, otherwise we'll be creative.
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template <class T_INT,
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bool T_INT_IS_UNSIGNED,
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class T_UNSIGNED_INT,
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T_INT T_INT_MIN,
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T_INT T_INT_MAX>
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static bool would_multiplication_overflow(T_INT a, T_INT b)
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{
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// Prevent accidental divisons by zero in this simple case.
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if ( !a || !b )
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return false;
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// Check if we have a 64-bit integer that it is large enough.
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if ( sizeof(T_INT)*2 <= sizeof(int64_t) )
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{
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int64_t ret_large = (int64_t) a * (int64_t) b;
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return ret_large < (int64_t) T_INT_MIN ||
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(int64_t) T_INT_MAX < ret_large;
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}
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// Check if we have a 128-bit integer that it is large enough.
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#if 64 <= __WORDSIZE
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if ( sizeof(T_INT)*2 <= sizeof(__int128) )
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{
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__int128 ret_large = (__int128) a * (__int128) b;
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return ret_large < (__int128) T_INT_MIN ||
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(__int128) T_INT_MAX < ret_large;
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}
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#endif
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// The fallback strategy is to determine the largest b given a that will not
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// overflow and then see if b is within range. This is trivial if in the
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// unsigned integer case.
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if ( T_INT_IS_UNSIGNED )
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{
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T_INT max_b = a / T_INT_MAX;
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return max_b < b;
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}
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// We have to deal with some cases for signed integers. We'll assume signed
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// integers are in two's complement and use - (unsigned int) value to take
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// the absolute value of a negative value as an unsigned integer in a manner
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// that is defined in C. Whether we use the smallest or largest value depend
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// on whether the sign of a and b is identical.
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else
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{
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T_UNSIGNED_INT a_abs = a < 0 ? - (T_UNSIGNED_INT) a : a;
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T_UNSIGNED_INT b_abs = b < 0 ? - (T_UNSIGNED_INT) b : b;
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T_UNSIGNED_INT min_abs = - (T_UNSIGNED_INT) T_INT_MIN;
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T_UNSIGNED_INT max_abs = T_INT_MAX;
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T_UNSIGNED_INT limit_pos = (0 <= a && 0 <= b) || ( a < 0 && b < 0 );
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T_UNSIGNED_INT limit = limit_pos ? max_abs : min_abs;
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T_UNSIGNED_INT max_b = a_abs / limit;
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return max_b < b_abs;
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}
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}
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extern "C"
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STRTOL_INT STRTOL(const STRTOL_CHAR* restrict str,
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STRTOL_CHAR** restrict endptr,
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int base)
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{
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const STRTOL_CHAR* origstr = str;
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int origbase = base;
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// Skip any leading white space.
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while ( STRTOL_ISSPACE(*str) )
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str++;
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// Reject bad bases.
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if ( base < 0 || 36 < base )
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{
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if ( endptr )
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*endptr = (STRTOL_CHAR*) str;
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return errno = EINVAL, 0;
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}
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bool negative = false;
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STRTOL_CHAR c = *str;
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// Handle a leading sign character.
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if ( c == STRTOL_L('-') )
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str++, negative = true;
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else if ( c == STRTOL_L('+') )
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str++, negative = false;
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// Autodetect base 8 or base 16.
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if ( !base && str[0] == STRTOL_L('0') )
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{
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if ( (str[1] == STRTOL_L('x') || str[1] == STRTOL_L('X')) &&
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(str[2] && debase(str[2]) < 16) )
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str += 2, base = 16;
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else if ( 0 <= debase(str[1]) )
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str++, base = 8;
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}
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// Default to base 10.
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if ( !base )
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base = 10;
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// Skip the leading '0x' prefix in base 16 for hexadecimal integers.
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if ( origbase == 16 &&
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str[0] == STRTOL_L('0') &&
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(str[1] == STRTOL_L('x') || str[1] == STRTOL_L('X')) &&
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(0 <= debase(str[2]) && debase(str[2]) < 16) )
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str += 2;
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// Determine what value will be returned on overflow/underflow.
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STRTOL_INT overflow_value = negative && !STRTOL_INT_IS_UNSIGNED ?
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STRTOL_INT_MIN :
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STRTOL_INT_MAX;
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// Convert a single character at a time.
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STRTOL_INT result = 0;
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size_t numconvertedchars = 0;
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bool overflow_occured = false;
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while ( (c = *str ) )
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{
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// Stop if we encounterd a character that doesn't fit in this base.
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int val = debase(c);
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if ( val < 0 || base <= val )
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break;
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// Attempt to multiply the accumulator with the current base.
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if ( would_multiplication_overflow<STRTOL_INT,
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STRTOL_INT_IS_UNSIGNED,
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STRTOL_UNSIGNED_INT,
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STRTOL_INT_MIN,
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STRTOL_INT_MAX>
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(result, (STRTOL_INT) base) )
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overflow_occured = true, result = overflow_value;
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else
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{
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STRTOL_INT new_result = result * (STRTOL_INT) base;
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assert( negative || result <= new_result);
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assert(!negative || result >= new_result);
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result = new_result;
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}
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// Attempt to add the latest digit to the accumulator (positive).
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if ( (STRTOL_INT_IS_UNSIGNED || !negative) &&
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(STRTOL_INT) val <= (STRTOL_INT) (STRTOL_INT_MAX - result) )
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result += (STRTOL_INT) val;
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// Attempt to subtract the latest digit to the accumulator (negative).
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else if ( (!STRTOL_INT_IS_UNSIGNED && negative) &&
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(STRTOL_UNSIGNED_INT) val < ((STRTOL_UNSIGNED_INT) result - (STRTOL_UNSIGNED_INT) STRTOL_INT_MIN) )
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result -= (STRTOL_INT) val;
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// Handle the case where the addition/subtract would overflow/underflow.
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else
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overflow_occured = true, result = overflow_value;
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str++;
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numconvertedchars++;
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}
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// If no characters were successfully converted, rewind to the start, also
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// rewinding past skipped whitespace and sign characters and such.
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if ( !numconvertedchars )
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str = origstr, result = 0;
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// Let the caller know where we got to.
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if ( endptr )
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*endptr = (STRTOL_CHAR*) str;
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// Handle the special case where we are creating an unsigned integer and the
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// string was negative and non-zero and no overflow occured, then we treat
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// it as (the maximum value+1) minus (the negative string as integer).
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if ( STRTOL_INT_IS_UNSIGNED && negative && result && !overflow_occured )
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result = STRTOL_INT_MAX - (result-1);
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return result;
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}
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