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banan-os/userspace/libraries/LibC/include/bits/strtoT.hpp

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7.7 KiB
C++

#ifndef _BITS_STRTOT_HPP
#define _BITS_STRTOT_HPP 1
#include <BAN/Math.h>
#include <errno.h>
#include <ctype.h>
#include <wchar.h>
template<typename CHAR>
struct strtoT_traits;
template<>
struct strtoT_traits<char>
{
static constexpr int (&isalnum)(int) = ::isalnum;
static constexpr int (&isalpha)(int) = ::isalpha;
static constexpr int (&isdigit)(int) = ::isdigit;
static constexpr int (&isspace)(int) = ::isspace;
static constexpr int (&isxdigit)(int) = ::isxdigit;
static constexpr int (&tolower)(int) = ::tolower;
static constexpr int (&strncasecmp)(const char*, const char*, size_t) = ::strncasecmp;
static constexpr const char* lit_0b = "0b";
static constexpr const char* lit_0x = "0x";
static constexpr const char* lit_inf = "inf";
static constexpr const char* lit_infinity = "infinity";
static constexpr const char* lit_nan = "nan";
};
template<>
struct strtoT_traits<wchar_t>
{
static constexpr int (&isalnum)(wint_t) = ::iswalnum;
static constexpr int (&isalpha)(wint_t) = ::iswalpha;
static constexpr int (&isdigit)(wint_t) = ::iswdigit;
static constexpr int (&isspace)(wint_t) = ::iswspace;
static constexpr int (&isxdigit)(wint_t) = ::iswxdigit;
static constexpr wint_t (&tolower)(wint_t) = ::towlower;
static constexpr int (&strncasecmp)(const wchar_t*, const wchar_t*, size_t) = ::wcsncasecmp;
static constexpr const wchar_t* lit_0x = L"0x";
static constexpr const wchar_t* lit_inf = L"inf";
static constexpr const wchar_t* lit_infinity = L"infinity";
static constexpr const wchar_t* lit_nan = L"nan";
};
template<BAN::integral T, typename CHAR>
static T strtoT(const CHAR* str, CHAR** endp, int base, int& error)
{
using traits = strtoT_traits<CHAR>;
constexpr auto will_digit_append_overflow = [](T current, int digit, int base) -> bool {
if (BAN::Math::will_multiplication_overflow<T>(current, base))
return true;
if (BAN::Math::will_addition_overflow<T>(current * base, current < 0 ? -digit : digit))
return true;
return false;
};
constexpr auto get_base_digit = [](CHAR c, int base) {
int digit = -1;
if (traits::isdigit(c))
digit = c - CHAR('0');
else if (traits::isalpha(c))
digit = 10 + traits::tolower(c) - CHAR('a');
if (digit < 0 || digit >= base)
digit = -1;
return digit;
};
const CHAR* orig_str = str;
// validate base
if (base != 0 && (base < 2 || base > 36))
{
if (endp)
*endp = const_cast<CHAR*>(str);
error = EINVAL;
return 0;
}
// skip whitespace
while (traits::isspace(*str))
str++;
// get sign and skip it
const bool negative = (*str == CHAR('-'));
if (*str == CHAR('-') || *str == CHAR('+'))
str++;
// determine base from prefix
if (base == 0)
{
if (*str != CHAR('0'))
base = 10;
else if (traits::tolower(str[1]) == CHAR('x'))
base = 16;
else
base = 8;
}
// check for invalid conversion
if (get_base_digit(*str, base) == -1)
{
if (endp)
*endp = const_cast<CHAR*>(orig_str);
error = EINVAL;
return 0;
}
// remove "0x" prefix from hexadecimal
if (base == 16 && traits::strncasecmp(str, traits::lit_0x, 2) == 0 && get_base_digit(str[2], base) != -1)
str += 2;
bool overflow = false;
T result = 0;
// calculate the value of the number in string
while (!overflow)
{
int digit = get_base_digit(*str, base);
if (digit == -1)
break;
str++;
overflow = will_digit_append_overflow(result, digit, base);
if (!overflow)
{
if (negative && !BAN::is_unsigned_v<T>)
digit = -digit;
result = result * base + digit;
}
}
if (negative && BAN::is_unsigned_v<T>)
result = -result;
// save endp if asked
if (endp)
{
while (get_base_digit(*str, base) != -1)
str++;
*endp = const_cast<CHAR*>(str);
}
// return error on overflow
if (overflow)
{
error = ERANGE;
if constexpr(BAN::is_unsigned_v<T>)
return BAN::numeric_limits<T>::max();
return negative ? BAN::numeric_limits<T>::min() : BAN::numeric_limits<T>::max();
}
return result;
}
template<BAN::floating_point T, typename CHAR>
static T strtoT(const CHAR* str, CHAR** endp, int& error)
{
using traits = strtoT_traits<CHAR>;
constexpr auto get_base_digit = [](CHAR c, int base) {
int digit = -1;
if (traits::isdigit(c))
digit = c - CHAR('0');
else if (traits::isalpha(c))
digit = 10 + traits::tolower(c) - CHAR('a');
if (digit < 0 || digit >= base)
digit = -1;
return digit;
};
// find nan end including possible n-char-sequence
const auto get_nan_end = [](const CHAR* str) -> const CHAR* {
ASSERT(traits::strncasecmp(str, traits::lit_nan, 3) == 0);
if (str[3] != CHAR('('))
return str + 3;
for (size_t i = 4; traits::isalnum(str[i]) || str[i] == CHAR('_'); i++)
if (str[i] == CHAR(')'))
return str + i + 1;
return str + 3;
};
// skip whitespace
while (traits::isspace(*str))
str++;
// get sign and skip it
const bool negative = (*str == CHAR('-'));
if (*str == CHAR('-') || *str == CHAR('+'))
str++;
// check for infinity or nan
{
T result = 0;
if (traits::strncasecmp(str, traits::lit_inf, 3) == 0)
{
result = BAN::numeric_limits<T>::infinity();
str += traits::strncasecmp(str, traits::lit_infinity, 8) ? 3 : 8;
}
else if (traits::strncasecmp(str, traits::lit_nan, 3) == 0)
{
result = BAN::numeric_limits<T>::quiet_NaN();
str = get_nan_end(str);
}
if (result != 0)
{
if (endp)
*endp = const_cast<CHAR*>(str);
return negative ? -result : result;
}
}
// no conversion can be performed -- not ([digit] || .[digit])
if (!(traits::isdigit(*str) || (str[0] == CHAR('.') && traits::isdigit(str[1]))))
{
if (endp)
*endp = const_cast<CHAR*>(str);
error = EINVAL;
return 0;
}
int base = 10;
int exponent = 0;
int exponents_per_digit = 1;
// check whether we have base 16 value -- (0x[xdigit] || 0x.[xdigit])
if (traits::strncasecmp(str, traits::lit_0x, 2) == 0 && (traits::isxdigit(str[2]) || (str[2] == CHAR('.') && traits::isxdigit(str[3]))))
{
base = 16;
exponents_per_digit = 4;
str += 2;
}
// parse whole part
T result = 0;
T multiplier = 1;
while (true)
{
int digit = get_base_digit(*str, base);
if (digit == -1)
break;
str++;
if (result)
exponent += exponents_per_digit;
if (digit)
result += multiplier * digit;
if (result)
multiplier /= base;
}
if (*str == CHAR('.'))
str++;
while (true)
{
const int digit = get_base_digit(*str, base);
if (digit == -1)
break;
str++;
if (result == 0)
exponent -= exponents_per_digit;
if (digit)
result += multiplier * digit;
if (result)
multiplier /= base;
}
if (traits::tolower(*str) == (base == 10 ? CHAR('e') : CHAR('p')))
{
CHAR* maybe_end = nullptr;
int exp_error = 0;
const int extra_exponent = strtoT<int>(str + 1, &maybe_end, 10, exp_error);
if (exp_error != EINVAL)
{
if (exp_error == ERANGE || BAN::Math::will_addition_overflow(exponent, extra_exponent))
exponent = negative ? BAN::numeric_limits<int>::min() : BAN::numeric_limits<int>::max();
else
exponent += extra_exponent;
str = maybe_end;
}
}
if (endp)
*endp = const_cast<CHAR*>(str);
// no over/underflow can happed with zero
if (result == 0)
return 0;
const int max_exponent = (base == 10) ? BAN::numeric_limits<T>::max_exponent10() : BAN::numeric_limits<T>::max_exponent2();
if (exponent > max_exponent)
{
error = ERANGE;
result = BAN::numeric_limits<T>::infinity();
return negative ? -result : result;
}
const int min_exponent = (base == 10) ? BAN::numeric_limits<T>::min_exponent10() : BAN::numeric_limits<T>::min_exponent2();
if (exponent < min_exponent)
{
error = ERANGE;
result = 0;
return negative ? -result : result;
}
if (exponent)
result *= BAN::Math::pow<T>((base == 10) ? 10 : 2, exponent);
return negative ? -result : result;
}
#endif