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|
// libunicode
//
// Author: Roland Reichwein
//
// Available under the conditions of CC0 1.0 Universal
// https://creativecommons.org/publicdomain/zero/1.0/
#pragma once
#include <algorithm>
#include <iterator>
#include <list>
#include <memory>
#include <stdexcept>
#include <string>
#include <type_traits>
#include <unordered_map>
#ifdef __cpp_char8_t
// char8_t available
typedef char8_t utf8_t;
#else
typedef char utf8_t;
#endif
typedef char iso_t;
namespace unicode {
// usually, char32_t, uint32_t etc.
template<typename T>
static inline bool is_valid_unicode(const T& value) noexcept
{
return value <= 0xD7FF || (value >= 0xE000 && value <= 0x10FFFF);
}
}
namespace unicode::detail {
using namespace std::string_literals;
template<typename T, typename Container=std::basic_string<T>>
struct utf_iterator
{
static_assert(sizeof(T) == 1 || sizeof(T) == 2 || sizeof(T) == 4);
typedef T input_type;
typedef char32_t value_type;
typedef char32_t& reference;
typedef char32_t* pointer;
typedef size_t difference_type;
typedef std::input_iterator_tag iterator_category;
typedef Container string_type;
utf_iterator(const typename string_type::const_iterator& cbegin, const typename string_type::const_iterator& cend):
iterator(cbegin), end_iterator(cend)
{
}
utf_iterator(const utf_iterator& other) = default;
utf_iterator& operator=(const utf_iterator& other) = default;
size_t remaining_code_units() const noexcept
{
return std::distance(iterator, end_iterator);
}
template<size_t index>
T get_code_unit() const noexcept
{
if constexpr (std::is_same<Container, typename std::list<T>>::value) {
// std::list doesn't support it + n
auto it{iterator};
std::advance(it, index);
return *it;
} else {
return *(iterator + index);
}
}
inline static bool is_continuation_byte(T b) noexcept
{
return (b & 0b11000000) == 0b10000000;
}
template<typename... Targs>
inline static bool is_continuation_byte(T b, Targs... Fargs) noexcept
{
return is_continuation_byte(b) && is_continuation_byte(Fargs...);
}
template<size_t n>
inline static bool is_byte0_of(T b) noexcept
{
return (b & static_cast<T>(0xFF << (7 - n))) == static_cast<T>(0xFF << (8 - n));
}
inline static char32_t continuation_value(T b) noexcept
{
return static_cast<char32_t>(b & 0b00111111);
}
template<typename... Targs>
inline static char32_t continuation_value(T b, Targs... Fargs) noexcept
{
return continuation_value(b) << (6 * sizeof...(Targs)) | continuation_value(Fargs...);
}
template<size_t n>
inline static char32_t value_byte0_of(T b) noexcept
{
return static_cast<char32_t>(b & (0b1111111 >> n)) << ((n - 1) * 6);
}
template<class X = T, typename std::enable_if<(sizeof(X) == 1), bool>::type = true>
inline value_type calculate_value()
{
size_t remaining{remaining_code_units()};
if (!remaining)
return {};
value_type value{};
utf8_t byte0 {static_cast<utf8_t>(get_code_unit<0>())};
if (byte0 & 0x80) { // 2-4 bytes
if (remaining >= 2) {
utf8_t byte1 {static_cast<utf8_t>(get_code_unit<1>())};
if (is_byte0_of<2>(byte0) && is_continuation_byte(byte1)) { // 2 bytes
value = value_byte0_of<2>(byte0) | continuation_value(byte1);
std::advance(iterator, 2);
} else if (remaining >= 3) {
utf8_t byte2 {static_cast<utf8_t>(get_code_unit<2>())};
if (is_byte0_of<3>(byte0) && is_continuation_byte(byte1, byte2)) { // 3 bytes
value = value_byte0_of<3>(byte0) | continuation_value(byte1, byte2);
std::advance(iterator, 3);
} else if (remaining >= 4) {
utf8_t byte3 {static_cast<utf8_t>(get_code_unit<3>())};
if (is_byte0_of<4>(byte0) && is_continuation_byte(byte1, byte2, byte3)) { // 4 bytes
value = value_byte0_of<4>(byte0) | continuation_value(byte1, byte2, byte3);
std::advance(iterator, 4);
} else
throw std::invalid_argument("Bad input: Invalid 4 byte sequence");
} else
throw std::invalid_argument("Bad input: Invalid 3 byte sequence");
} else
throw std::invalid_argument("Bad input: Invalid 2 byte sequence");
} else
throw std::invalid_argument("Bad input: 2nd byte expected, none found");
// check only for sequences >= 2 bytes (ASCII is always compliant)
if (!unicode::is_valid_unicode(value))
throw std::invalid_argument("Invalid Unicode character: "s + std::to_string(static_cast<uint32_t>(value)));
} else { // 1 byte: 7 bit ASCII
value = byte0;
std::advance(iterator, 1);
}
return value;
}
template<class X = T, typename std::enable_if<(sizeof(X) == 2), bool>::type = true>
inline value_type calculate_value()
{
size_t remaining{remaining_code_units()};
if (!remaining)
return {};
char16_t unit0 {static_cast<char16_t>(get_code_unit<0>())};
if (unit0 <= 0xD7FF || unit0 >= 0xE000) { // 1 unit (BMP Basic Multilingual Plane)
std::advance(iterator, 1);
return unit0;
} else {
if (remaining < 2)
throw std::invalid_argument("Bad input: Continuation of first UTF-16 unit missing");
char16_t unit1 {static_cast<char16_t>(get_code_unit<1>())};
if ((unit0 & 0xFC00) != 0xD800 || (unit1 & 0xFC00) != 0xDC00)
throw std::invalid_argument("Bad input: 2 malformed UTF-16 surrogates");
std::advance(iterator, 2);
return (static_cast<char32_t>(unit0 & 0x03FF) << 10 | (unit1 & 0x03FF)) + 0x10000;
}
}
template<class X = T, typename std::enable_if<(sizeof(X) == 4), bool>::type = true>
inline value_type calculate_value()
{
size_t remaining{remaining_code_units()};
if (!remaining)
return {};
value_type result {static_cast<char32_t>(get_code_unit<0>())};
if (!unicode::is_valid_unicode(result))
throw std::invalid_argument("Invalid Unicode character: "s + std::to_string(static_cast<uint32_t>(result)));
std::advance(iterator, 1);
return result;
}
// pre-increment
utf_iterator& operator++()
{
return *this;
}
bool operator!=(const utf_iterator& other) const
{
return std::distance(iterator, end_iterator) != std::distance(other.iterator, other.end_iterator);
}
value_type operator*()
{
return calculate_value();
}
private:
typename string_type::const_iterator iterator;
typename string_type::const_iterator end_iterator;
};
template<typename T, typename Container=std::basic_string<T>>
struct utf_back_insert_iterator
{
static_assert(sizeof(T) == 1 || sizeof(T) == 2 || sizeof(T) == 4);
typedef T value_type;
typedef Container string_type;
typedef utf_back_insert_iterator& reference;
typedef utf_back_insert_iterator* pointer;
typedef size_t difference_type;
typedef std::output_iterator_tag iterator_category;
utf_back_insert_iterator(string_type& s): s(s) {}
utf_back_insert_iterator& operator=(const utf_back_insert_iterator& other)
{
if (std::addressof(other.s) != std::addressof(s))
throw std::runtime_error("utf_back_insert_iterator assignment operator actually called! Iterator should not be assigned to.");
return *this;
}
// no-op
reference operator++()
{
return *this;
}
// support *x = value, together with operator=()
reference operator*()
{
return *this;
}
// n is number of UTF-8 bytes in sequence
template<size_t n>
inline static T byte0_of(char32_t value)
{
return (value >> 6 * (n - 1)) | (0xFF << (8 - n));
}
// n is index of 6-bit groups, counting from bit 0
template<size_t n>
inline static T trailing_byte(char32_t value)
{
return ((value >> n * 6) & 0b111111) | 0b10000000;
}
// calculate UTF-8 sequence byte for m >= 2 bytes sequences (i.e. non-ASCII)
// assume value to be valid Unicode value for given byte position
template<size_t n, size_t m>
inline static T byte_n_of_m(char32_t value)
{
if constexpr (n == 0)
return byte0_of<m>(value);
else
return trailing_byte<m - n - 1>(value);
}
void append_utf8(const char32_t& value)
{
if (value < 0x80) { // 1 byte
s.push_back(static_cast<value_type>(value));
} else if (value < 0x800) { // 2 bytes
s.push_back(byte_n_of_m<0,2>(value));
s.push_back(byte_n_of_m<1,2>(value));
} else if (value < 0x10000) { // 3 bytes
s.push_back(byte_n_of_m<0,3>(value));
s.push_back(byte_n_of_m<1,3>(value));
s.push_back(byte_n_of_m<2,3>(value));
} else if (value < 0x110000) { // 4 bytes
s.push_back(byte_n_of_m<0,4>(value));
s.push_back(byte_n_of_m<1,4>(value));
s.push_back(byte_n_of_m<2,4>(value));
s.push_back(byte_n_of_m<3,4>(value));
} else
throw std::runtime_error("Invalid internal Unicode value: "s + std::to_string(static_cast<uint32_t>(value)));
}
void append_utf16(const char32_t& value)
{
if (value <= 0xFFFF) { // expect value to be already valid Unicode values
s.push_back(static_cast<value_type>(value));
} else {
char32_t value_reduced{value - 0x10000};
s.push_back((value_reduced >> 10) + 0xD800);
s.push_back((value_reduced & 0x3FF) + 0xDC00);
}
}
void append_utf32(const char32_t& value)
{
// expect value to be already valid Unicode values
s.push_back(value);
}
reference operator=(const char32_t& value)
{
static_assert(sizeof(T) == 1 || sizeof(T) == 2 || sizeof(T) == 4);
if constexpr(sizeof(T) == 1) {
append_utf8(value);
} else if constexpr(sizeof(T) == 2) {
append_utf16(value);
} else if constexpr(sizeof(T) == 4) {
append_utf32(value);
}
return *this;
}
private:
typename utf_back_insert_iterator::string_type& s;
};
typedef std::unordered_map<iso_t, char32_t> iso_map_type;
typedef std::unordered_map<char32_t, iso_t> iso_map_type_reverse;
// ISO-8859-1 is lower 8-bit of Unicode, so no exceptions necessary
static inline iso_map_type iso_8859_1_map;
// ISO-8859-15 is lower 8-bit of Unicode, except for:
static inline iso_map_type iso_8859_15_map {
{ '\xA4', U'\u20AC' }, // €
{ '\xA6', U'\u0160' }, // Š
{ '\xA8', U'\u0161' }, // š
{ '\xB4', U'\u017D' }, // Ž
{ '\xB8', U'\u017E' }, // ž
{ '\xBC', U'\u0152' }, // Œ
{ '\xBD', U'\u0153' }, // œ
{ '\xBE', U'\u0178' }, // Ÿ
};
inline iso_map_type_reverse reverse_iso_map(const iso_map_type& map) {
iso_map_type_reverse result;
std::for_each(map.cbegin(), map.cend(),
[&](const iso_map_type::value_type& pair)
{
result.emplace(pair.second, pair.first);
});
return result;
}
static inline iso_map_type_reverse iso_8859_15_map_reverse { reverse_iso_map(iso_8859_15_map) };
static inline iso_map_type_reverse iso_8859_1_map_reverse { reverse_iso_map(iso_8859_1_map) };
} // namespace unicode::detail
namespace unicode {
using namespace detail;
template<unicode::detail::iso_map_type& Map=iso_8859_1_map, typename Container=std::basic_string<iso_t>>
struct iso_iterator {
typedef iso_t input_type;
typedef char32_t value_type;
typedef char32_t& reference;
typedef char32_t* pointer;
typedef size_t difference_type;
typedef std::input_iterator_tag iterator_category;
typedef typename Container::const_iterator iterator;
typedef Container string_type;
iso_iterator(const iterator& it): m_it(it) {}
// pre-increment
iso_iterator& operator++()
{
++m_it;
return *this;
}
bool operator!=(const iso_iterator& other) const
{
return m_it != other.m_it;
}
// return reference?
value_type operator*()
{
input_type value{*m_it};
if constexpr(std::addressof(Map) != std::addressof(iso_8859_1_map)) // mapping of 128 <= x <= 255 needed
{
auto it{Map.find(value)};
if (it != Map.end())
return it->second;
}
return static_cast<value_type>(static_cast<uint8_t>(value));
}
private:
iterator m_it;
};
template<unicode::detail::iso_map_type_reverse& Map=iso_8859_1_map_reverse, typename Container=std::basic_string<iso_t>>
struct iso_back_insert_iterator {
typedef iso_back_insert_iterator& reference;
typedef iso_back_insert_iterator* pointer;
typedef size_t difference_type;
typedef iso_t value_type;
typedef std::output_iterator_tag iterator_category;
typedef Container string_type;
iso_back_insert_iterator(string_type& s): s(s) {}
iso_back_insert_iterator& operator=(const iso_back_insert_iterator& other)
{
if (std::addressof(other.s) != std::addressof(s))
throw std::runtime_error("iso_back_insert_iterator assignment operator actually called! Iterator should not be assigned to.");
return *this;
}
// no-op
reference operator++()
{
return *this;
}
// support *x = value, together with operator=()
reference operator*()
{
return *this;
}
reference operator=(const char32_t& value)
{
if constexpr(std::addressof(Map) != std::addressof(iso_8859_1_map_reverse)) // mapping of 128 <= x <= 255 needed
{
auto it{Map.find(value)};
if (it != Map.end()) {
s.push_back(it->second);
return *this;
}
}
if (value > 255)
throw std::invalid_argument("Bad ISO 8859 value above 255: "s + std::to_string(static_cast<uint32_t>(value)));
s.push_back(static_cast<typename iso_back_insert_iterator::value_type>(value));
return *this;
}
private:
typename iso_back_insert_iterator::string_type& s;
};
// Facet for convert() and ISO-8859-*
template<typename InputIt, typename OutputIt>
struct ISO_8859
{
typedef iso_t value_type;
typedef typename InputIt::string_type string_type;
static InputIt begin(const typename InputIt::string_type& s)
{
return InputIt(s.cbegin());
}
static InputIt end(const typename InputIt::string_type& s)
{
return InputIt(s.cend());
}
static OutputIt back_inserter(typename OutputIt::string_type& s)
{
return OutputIt(s);
}
};
// Facet for convert() and UTF-*
template<typename InputIt, typename OutputIt>
struct UTF
{
typedef typename OutputIt::value_type value_type;
typedef typename InputIt::string_type string_type;
static InputIt begin(const typename InputIt::string_type& s)
{
return InputIt{s.cbegin(), s.cend()};
}
static InputIt end(const typename InputIt::string_type& s)
{
return InputIt{s.cend(), s.cend()};
}
static OutputIt back_inserter(typename OutputIt::string_type& s)
{
return OutputIt(s);
}
};
// Facet for convert()
typedef ISO_8859<iso_iterator<>, iso_back_insert_iterator<>> ISO_8859_1;
typedef ISO_8859<iso_iterator<iso_8859_15_map>, iso_back_insert_iterator<iso_8859_15_map_reverse>> ISO_8859_15;
typedef UTF<utf_iterator<utf8_t>, utf_back_insert_iterator<utf8_t>> UTF_8;
typedef UTF<utf_iterator<char16_t>, utf_back_insert_iterator<char16_t>> UTF_16;
typedef UTF<utf_iterator<char32_t>, utf_back_insert_iterator<char32_t>> UTF_32;
// From and To are facets
template<typename From, typename To, std::enable_if_t<std::is_empty<From>::value, bool> = true>
typename To::string_type convert(const typename From::string_type& s)
{
typename To::string_type result;
std::copy(From::begin(s), From::end(s), To::back_inserter(result));
return result;
}
// Helper to get correct Facet from char type, e.g. Encoding<typename decltype(s)::value_type>::Facet
template<typename T>
struct Encoding
{
};
template<>
struct Encoding<utf8_t>
{
typedef UTF_8 Facet;
};
template<>
struct Encoding<char16_t>
{
typedef UTF_16 Facet;
};
template<>
struct Encoding<char32_t>
{
typedef UTF_32 Facet;
};
// From and To are from: utf8_t (i.e. char or char8_t (C++20)), char16_t and char32_t, char, wchar_t, uint8_t, uint16_t, uint32_t
template<typename From, typename To,
typename FromContainer=std::basic_string<From>,
typename ToContainer=std::basic_string<To>,
std::enable_if_t<std::is_trivial<From>::value && std::is_scalar<From>::value && !std::is_empty<From>::value, bool> = true>
ToContainer convert(const FromContainer& s)
{
typedef UTF<utf_iterator<From>, utf_back_insert_iterator<To>> UTF_Trait;
ToContainer result;
std::copy(UTF_Trait::begin(s), UTF_Trait::end(s), UTF_Trait::back_inserter(result));
return result;
}
// From and To are containers
template<typename FromContainer, typename ToContainer,
std::enable_if_t<!std::is_empty<FromContainer>::value && !std::is_empty<ToContainer>::value, bool> = true
>
ToContainer convert(const FromContainer& s)
{
typedef UTF<utf_iterator<typename FromContainer::value_type, FromContainer>, utf_back_insert_iterator<typename ToContainer::value_type, ToContainer>> UTF_Trait;
ToContainer result;
std::copy(UTF_Trait::begin(s), UTF_Trait::end(s), UTF_Trait::back_inserter(result));
return result;
}
// Container version
template<typename Container, std::enable_if_t<!std::is_empty<Container>::value, bool> = true>
bool is_valid_utf(const Container& s)
{
typedef UTF<utf_iterator<typename Container::value_type, Container>, utf_back_insert_iterator<typename Container::value_type, Container>> UTF_Trait;
try {
std::for_each(UTF_Trait::begin(s), UTF_Trait::end(s), [](const char32_t& c){});
} catch (const std::invalid_argument&) {
return false;
}
return true;
}
// basic type version
template<typename T,
typename Container=std::basic_string<T>,
std::enable_if_t<std::is_trivial<T>::value && !std::is_empty<T>::value, bool> = true>
bool is_valid_utf(const Container& s)
{
typedef UTF<utf_iterator<T>, utf_back_insert_iterator<T>> UTF_Trait;
try {
std::for_each(UTF_Trait::begin(s), UTF_Trait::end(s), [](const char32_t& c){});
} catch (const std::invalid_argument&) {
return false;
}
return true;
}
// Facet version
template<typename Facet, std::enable_if_t<std::is_empty<Facet>::value, bool> = true>
bool is_valid_utf(const typename Facet::string_type& s)
{
try {
std::for_each(Facet::begin(s), Facet::end(s), [](const char32_t& c){});
} catch (const std::invalid_argument&) {
return false;
}
return true;
}
} // namespace unicode
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