/* * * Copyright (c) 2004 * John Maddock * * Use, modification and distribution are subject to the * Boost Software License, Version 1.0. (See accompanying file * LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) * */ /* * LOCATION: see http://www.boost.org for most recent version. * FILE unicode_iterator.hpp * VERSION see * DESCRIPTION: Iterator adapters for converting between different Unicode encodings. */ /**************************************************************************** Contents: ~~~~~~~~~ 1) Read Only, Input Adapters: ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ template class u32_to_u8_iterator; Adapts sequence of UTF-32 code points to "look like" a sequence of UTF-8. template class u8_to_u32_iterator; Adapts sequence of UTF-8 code points to "look like" a sequence of UTF-32. template class u32_to_u16_iterator; Adapts sequence of UTF-32 code points to "look like" a sequence of UTF-16. template class u16_to_u32_iterator; Adapts sequence of UTF-16 code points to "look like" a sequence of UTF-32. 2) Single pass output iterator adapters: template class utf8_output_iterator; Accepts UTF-32 code points and forwards them on as UTF-8 code points. template class utf16_output_iterator; Accepts UTF-32 code points and forwards them on as UTF-16 code points. ****************************************************************************/ #ifndef BOOST_REGEX_UNICODE_ITERATOR_HPP #define BOOST_REGEX_UNICODE_ITERATOR_HPP #include #include #include #include #include #include #ifndef BOOST_NO_STD_LOCALE #include #include #endif #include // CHAR_BIT namespace boost{ namespace detail{ static const ::boost::uint16_t high_surrogate_base = 0xD7C0u; static const ::boost::uint16_t low_surrogate_base = 0xDC00u; static const ::boost::uint32_t ten_bit_mask = 0x3FFu; inline bool is_high_surrogate(::boost::uint16_t v) { return (v & 0xFC00u) == 0xd800u; } inline bool is_low_surrogate(::boost::uint16_t v) { return (v & 0xFC00u) == 0xdc00u; } template inline bool is_surrogate(T v) { return (v & 0xF800u) == 0xd800; } inline unsigned utf8_byte_count(boost::uint8_t c) { // if the most significant bit with a zero in it is in position // 8-N then there are N bytes in this UTF-8 sequence: boost::uint8_t mask = 0x80u; unsigned result = 0; while(c & mask) { ++result; mask >>= 1; } return (result == 0) ? 1 : ((result > 4) ? 4 : result); } inline unsigned utf8_trailing_byte_count(boost::uint8_t c) { return utf8_byte_count(c) - 1; } inline void invalid_utf32_code_point(::boost::uint32_t val) { #ifndef BOOST_NO_STD_LOCALE std::stringstream ss; ss << "Invalid UTF-32 code point U+" << std::showbase << std::hex << val << " encountered while trying to encode UTF-16 sequence"; std::out_of_range e(ss.str()); #else std::out_of_range e("Invalid UTF-32 code point encountered while trying to encode UTF-16 sequence"); #endif boost::throw_exception(e); } } // namespace detail template class u32_to_u16_iterator : public boost::iterator_facade, U16Type, std::bidirectional_iterator_tag, const U16Type> { typedef boost::iterator_facade, U16Type, std::bidirectional_iterator_tag, const U16Type> base_type; #if !defined(BOOST_NO_STD_ITERATOR_TRAITS) && !defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION) typedef typename std::iterator_traits::value_type base_value_type; BOOST_STATIC_ASSERT(sizeof(base_value_type)*CHAR_BIT == 32); BOOST_STATIC_ASSERT(sizeof(U16Type)*CHAR_BIT == 16); #endif public: typename base_type::reference dereference()const { if(m_current == 2) extract_current(); return m_values[m_current]; } bool equal(const u32_to_u16_iterator& that)const { if(m_position == that.m_position) { // Both m_currents must be equal, or both even // this is the same as saying their sum must be even: return (m_current + that.m_current) & 1u ? false : true; } return false; } void increment() { // if we have a pending read then read now, so that we know whether // to skip a position, or move to a low-surrogate: if(m_current == 2) { // pending read: extract_current(); } // move to the next surrogate position: ++m_current; // if we've reached the end skip a position: if(m_values[m_current] == 0) { m_current = 2; ++m_position; } } void decrement() { if(m_current != 1) { // decrementing an iterator always leads to a valid position: --m_position; extract_current(); m_current = m_values[1] ? 1 : 0; } else { m_current = 0; } } BaseIterator base()const { return m_position; } // construct: u32_to_u16_iterator() : m_position(), m_current(0) { m_values[0] = 0; m_values[1] = 0; m_values[2] = 0; } u32_to_u16_iterator(BaseIterator b) : m_position(b), m_current(2) { m_values[0] = 0; m_values[1] = 0; m_values[2] = 0; } private: void extract_current()const { // begin by checking for a code point out of range: ::boost::uint32_t v = *m_position; if(v >= 0x10000u) { if(v > 0x10FFFFu) detail::invalid_utf32_code_point(*m_position); // split into two surrogates: m_values[0] = static_cast(v >> 10) + detail::high_surrogate_base; m_values[1] = static_cast(v & detail::ten_bit_mask) + detail::low_surrogate_base; m_current = 0; BOOST_ASSERT(detail::is_high_surrogate(m_values[0])); BOOST_ASSERT(detail::is_low_surrogate(m_values[1])); } else { // 16-bit code point: m_values[0] = static_cast(*m_position); m_values[1] = 0; m_current = 0; // value must not be a surrogate: if(detail::is_surrogate(m_values[0])) detail::invalid_utf32_code_point(*m_position); } } BaseIterator m_position; mutable U16Type m_values[3]; mutable unsigned m_current; }; template class u16_to_u32_iterator : public boost::iterator_facade, U32Type, std::bidirectional_iterator_tag, const U32Type> { typedef boost::iterator_facade, U32Type, std::bidirectional_iterator_tag, const U32Type> base_type; // special values for pending iterator reads: BOOST_STATIC_CONSTANT(U32Type, pending_read = 0xffffffffu); #if !defined(BOOST_NO_STD_ITERATOR_TRAITS) && !defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION) typedef typename std::iterator_traits::value_type base_value_type; BOOST_STATIC_ASSERT(sizeof(base_value_type)*CHAR_BIT == 16); BOOST_STATIC_ASSERT(sizeof(U32Type)*CHAR_BIT == 32); #endif public: typename base_type::reference dereference()const { if(m_value == pending_read) extract_current(); return m_value; } bool equal(const u16_to_u32_iterator& that)const { return m_position == that.m_position; } void increment() { // skip high surrogate first if there is one: if(detail::is_high_surrogate(*m_position)) ++m_position; ++m_position; m_value = pending_read; } void decrement() { --m_position; // if we have a low surrogate then go back one more: if(detail::is_low_surrogate(*m_position)) --m_position; m_value = pending_read; } BaseIterator base()const { return m_position; } // construct: u16_to_u32_iterator() : m_position() { m_value = pending_read; } u16_to_u32_iterator(BaseIterator b) : m_position(b) { m_value = pending_read; } private: static void invalid_code_point(::boost::uint16_t val) { #ifndef BOOST_NO_STD_LOCALE std::stringstream ss; ss << "Misplaced UTF-16 surrogate U+" << std::showbase << std::hex << val << " encountered while trying to encode UTF-32 sequence"; std::out_of_range e(ss.str()); #else std::out_of_range e("Misplaced UTF-16 surrogate encountered while trying to encode UTF-32 sequence"); #endif boost::throw_exception(e); } void extract_current()const { m_value = static_cast(static_cast< ::boost::uint16_t>(*m_position)); // if the last value is a high surrogate then adjust m_position and m_value as needed: if(detail::is_high_surrogate(*m_position)) { // precondition; next value must have be a low-surrogate: BaseIterator next(m_position); ::boost::uint16_t t = *++next; if((t & 0xFC00u) != 0xDC00u) invalid_code_point(t); m_value = (m_value - detail::high_surrogate_base) << 10; m_value |= (static_cast(static_cast< ::boost::uint16_t>(t)) & detail::ten_bit_mask); } // postcondition; result must not be a surrogate: if(detail::is_surrogate(m_value)) invalid_code_point(static_cast< ::boost::uint16_t>(m_value)); } BaseIterator m_position; mutable U32Type m_value; }; template class u32_to_u8_iterator : public boost::iterator_facade, U8Type, std::bidirectional_iterator_tag, const U8Type> { typedef boost::iterator_facade, U8Type, std::bidirectional_iterator_tag, const U8Type> base_type; #if !defined(BOOST_NO_STD_ITERATOR_TRAITS) && !defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION) typedef typename std::iterator_traits::value_type base_value_type; BOOST_STATIC_ASSERT(sizeof(base_value_type)*CHAR_BIT == 32); BOOST_STATIC_ASSERT(sizeof(U8Type)*CHAR_BIT == 8); #endif public: typename base_type::reference dereference()const { if(m_current == 4) extract_current(); return m_values[m_current]; } bool equal(const u32_to_u8_iterator& that)const { if(m_position == that.m_position) { // either the m_current's must be equal, or one must be 0 and // the other 4: which means neither must have bits 1 or 2 set: return (m_current == that.m_current) || (((m_current | that.m_current) & 3) == 0); } return false; } void increment() { // if we have a pending read then read now, so that we know whether // to skip a position, or move to a low-surrogate: if(m_current == 4) { // pending read: extract_current(); } // move to the next surrogate position: ++m_current; // if we've reached the end skip a position: if(m_values[m_current] == 0) { m_current = 4; ++m_position; } } void decrement() { if((m_current & 3) == 0) { --m_position; extract_current(); m_current = 3; while(m_current && (m_values[m_current] == 0)) --m_current; } else --m_current; } BaseIterator base()const { return m_position; } // construct: u32_to_u8_iterator() : m_position(), m_current(0) { m_values[0] = 0; m_values[1] = 0; m_values[2] = 0; m_values[3] = 0; m_values[4] = 0; } u32_to_u8_iterator(BaseIterator b) : m_position(b), m_current(4) { m_values[0] = 0; m_values[1] = 0; m_values[2] = 0; m_values[3] = 0; m_values[4] = 0; } private: void extract_current()const { boost::uint32_t c = *m_position; if(c > 0x10FFFFu) detail::invalid_utf32_code_point(c); if(c < 0x80u) { m_values[0] = static_cast(c); m_values[1] = static_cast(0u); m_values[2] = static_cast(0u); m_values[3] = static_cast(0u); } else if(c < 0x800u) { m_values[0] = static_cast(0xC0u + (c >> 6)); m_values[1] = static_cast(0x80u + (c & 0x3Fu)); m_values[2] = static_cast(0u); m_values[3] = static_cast(0u); } else if(c < 0x10000u) { m_values[0] = static_cast(0xE0u + (c >> 12)); m_values[1] = static_cast(0x80u + ((c >> 6) & 0x3Fu)); m_values[2] = static_cast(0x80u + (c & 0x3Fu)); m_values[3] = static_cast(0u); } else { m_values[0] = static_cast(0xF0u + (c >> 18)); m_values[1] = static_cast(0x80u + ((c >> 12) & 0x3Fu)); m_values[2] = static_cast(0x80u + ((c >> 6) & 0x3Fu)); m_values[3] = static_cast(0x80u + (c & 0x3Fu)); } m_current= 0; } BaseIterator m_position; mutable U8Type m_values[5]; mutable unsigned m_current; }; template class u8_to_u32_iterator : public boost::iterator_facade, U32Type, std::bidirectional_iterator_tag, const U32Type> { typedef boost::iterator_facade, U32Type, std::bidirectional_iterator_tag, const U32Type> base_type; // special values for pending iterator reads: BOOST_STATIC_CONSTANT(U32Type, pending_read = 0xffffffffu); #if !defined(BOOST_NO_STD_ITERATOR_TRAITS) && !defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION) typedef typename std::iterator_traits::value_type base_value_type; BOOST_STATIC_ASSERT(sizeof(base_value_type)*CHAR_BIT == 8); BOOST_STATIC_ASSERT(sizeof(U32Type)*CHAR_BIT == 32); #endif public: typename base_type::reference dereference()const { if(m_value == pending_read) extract_current(); return m_value; } bool equal(const u8_to_u32_iterator& that)const { return m_position == that.m_position; } void increment() { // skip high surrogate first if there is one: unsigned c = detail::utf8_byte_count(*m_position); std::advance(m_position, c); m_value = pending_read; } void decrement() { // Keep backtracking until we don't have a trailing character: unsigned count = 0; while((*--m_position & 0xC0u) == 0x80u) ++count; // now check that the sequence was valid: if(count != detail::utf8_trailing_byte_count(*m_position)) invalid_sequnce(); m_value = pending_read; } BaseIterator base()const { return m_position; } // construct: u8_to_u32_iterator() : m_position() { m_value = pending_read; } u8_to_u32_iterator(BaseIterator b) : m_position(b) { m_value = pending_read; } private: static void invalid_sequnce() { std::out_of_range e("Invalid UTF-8 sequence encountered while trying to encode UTF-32 character"); boost::throw_exception(e); } void extract_current()const { m_value = static_cast(static_cast< ::boost::uint8_t>(*m_position)); // we must not have a continuation character: if((m_value & 0xC0u) == 0x80u) invalid_sequnce(); // see how many extra byts we have: unsigned extra = detail::utf8_trailing_byte_count(*m_position); // extract the extra bits, 6 from each extra byte: BaseIterator next(m_position); for(unsigned c = 0; c < extra; ++c) { ++next; m_value <<= 6; m_value += static_cast(*next) & 0x3Fu; } // we now need to remove a few of the leftmost bits, but how many depends // upon how many extra bytes we've extracted: static const boost::uint32_t masks[4] = { 0x7Fu, 0x7FFu, 0xFFFFu, 0x1FFFFFu, }; m_value &= masks[extra]; // check the result: if(m_value > static_cast(0x10FFFFu)) invalid_sequnce(); } BaseIterator m_position; mutable U32Type m_value; }; template class utf16_output_iterator { public: typedef void difference_type; typedef void value_type; typedef boost::uint32_t* pointer; typedef boost::uint32_t& reference; typedef std::output_iterator_tag iterator_category; utf16_output_iterator(const BaseIterator& b) : m_position(b){} utf16_output_iterator(const utf16_output_iterator& that) : m_position(that.m_position){} utf16_output_iterator& operator=(const utf16_output_iterator& that) { m_position = that.m_position; return *this; } const utf16_output_iterator& operator*()const { return *this; } void operator=(boost::uint32_t val)const { push(val); } utf16_output_iterator& operator++() { return *this; } utf16_output_iterator& operator++(int) { return *this; } BaseIterator base()const { return m_position; } private: void push(boost::uint32_t v)const { if(v >= 0x10000u) { // begin by checking for a code point out of range: if(v > 0x10FFFFu) detail::invalid_utf32_code_point(v); // split into two surrogates: *m_position++ = static_cast(v >> 10) + detail::high_surrogate_base; *m_position++ = static_cast(v & detail::ten_bit_mask) + detail::low_surrogate_base; } else { // 16-bit code point: // value must not be a surrogate: if(detail::is_surrogate(v)) detail::invalid_utf32_code_point(v); *m_position++ = static_cast(v); } } mutable BaseIterator m_position; }; template class utf8_output_iterator { public: typedef void difference_type; typedef void value_type; typedef boost::uint32_t* pointer; typedef boost::uint32_t& reference; typedef std::output_iterator_tag iterator_category; utf8_output_iterator(const BaseIterator& b) : m_position(b){} utf8_output_iterator(const utf8_output_iterator& that) : m_position(that.m_position){} utf8_output_iterator& operator=(const utf8_output_iterator& that) { m_position = that.m_position; return *this; } const utf8_output_iterator& operator*()const { return *this; } void operator=(boost::uint32_t val)const { push(val); } utf8_output_iterator& operator++() { return *this; } utf8_output_iterator& operator++(int) { return *this; } BaseIterator base()const { return m_position; } private: void push(boost::uint32_t c)const { if(c > 0x10FFFFu) detail::invalid_utf32_code_point(c); if(c < 0x80u) { *m_position++ = static_cast(c); } else if(c < 0x800u) { *m_position++ = static_cast(0xC0u + (c >> 6)); *m_position++ = static_cast(0x80u + (c & 0x3Fu)); } else if(c < 0x10000u) { *m_position++ = static_cast(0xE0u + (c >> 12)); *m_position++ = static_cast(0x80u + ((c >> 6) & 0x3Fu)); *m_position++ = static_cast(0x80u + (c & 0x3Fu)); } else { *m_position++ = static_cast(0xF0u + (c >> 18)); *m_position++ = static_cast(0x80u + ((c >> 12) & 0x3Fu)); *m_position++ = static_cast(0x80u + ((c >> 6) & 0x3Fu)); *m_position++ = static_cast(0x80u + (c & 0x3Fu)); } } mutable BaseIterator m_position; }; } // namespace boost #endif // BOOST_REGEX_UNICODE_ITERATOR_HPP