/* * Copyright (c) 2019-2020, Sergey Bugaev * Copyright (c) 2021, Max Wipfli * * SPDX-License-Identifier: BSD-2-Clause */ #pragma once #include #include #include #include #include namespace AK { class Utf8View; class Utf8CodePointIterator { friend class Utf8View; public: Utf8CodePointIterator() = default; ~Utf8CodePointIterator() = default; bool operator==(Utf8CodePointIterator const&) const = default; bool operator!=(Utf8CodePointIterator const&) const = default; Utf8CodePointIterator& operator++(); u32 operator*() const; // NOTE: This returns {} if the peek is at or past EOF. Optional peek(size_t offset = 0) const; ssize_t operator-(Utf8CodePointIterator const& other) const { return m_ptr - other.m_ptr; } u8 const* ptr() const { return m_ptr; } // Note : These methods return the information about the underlying UTF-8 bytes. // If the UTF-8 string encoding is not valid at the iterator's position, then the underlying bytes might be different from the // decoded character's re-encoded bytes (which will be an `0xFFFD REPLACEMENT CHARACTER` with an UTF-8 length of three bytes). // If your code relies on the decoded character being equivalent to the re-encoded character, use the `UTF8View::validate()` // method on the view prior to using its iterator. size_t underlying_code_point_length_in_bytes() const; ReadonlyBytes underlying_code_point_bytes() const { return { m_ptr, underlying_code_point_length_in_bytes() }; } bool done() const { return m_length == 0; } private: Utf8CodePointIterator(u8 const* ptr, size_t length) : m_ptr(ptr) , m_length(length) { } u8 const* m_ptr { nullptr }; size_t m_length { 0 }; }; class Utf8View { public: using Iterator = Utf8CodePointIterator; Utf8View() = default; explicit constexpr Utf8View(StringView string) : m_string(string) { } explicit Utf8View(ByteString& string) : m_string(string.view()) { } explicit Utf8View(ByteString&&) = delete; enum class AllowSurrogates { Yes, No, }; ~Utf8View() = default; StringView as_string() const { return m_string; } Utf8CodePointIterator begin() const { return { begin_ptr(), m_string.length() }; } Utf8CodePointIterator end() const { return { end_ptr(), 0 }; } Utf8CodePointIterator iterator_at_byte_offset(size_t) const; Utf8CodePointIterator iterator_at_byte_offset_without_validation(size_t) const; unsigned char const* bytes() const { return begin_ptr(); } size_t byte_length() const { return m_string.length(); } [[nodiscard]] size_t byte_offset_of(Utf8CodePointIterator const& it) const { VERIFY(it.m_ptr >= begin_ptr()); VERIFY(it.m_ptr <= end_ptr()); return it.m_ptr - begin_ptr(); } size_t byte_offset_of(size_t code_point_offset) const; Utf8View substring_view(size_t byte_offset, size_t byte_length) const { return Utf8View { m_string.substring_view(byte_offset, byte_length) }; } Utf8View substring_view(size_t byte_offset) const { return substring_view(byte_offset, byte_length() - byte_offset); } Utf8View unicode_substring_view(size_t code_point_offset, size_t code_point_length) const; Utf8View unicode_substring_view(size_t code_point_offset) const { return unicode_substring_view(code_point_offset, length() - code_point_offset); } bool is_empty() const { return m_string.is_empty(); } bool is_null() const { return m_string.is_null(); } bool starts_with(Utf8View const&) const; bool contains(u32) const; Utf8View trim(Utf8View const& characters, TrimMode mode = TrimMode::Both) const; size_t iterator_offset(Utf8CodePointIterator const& it) const { return byte_offset_of(it); } size_t length() const { if (!m_have_length) { m_length = calculate_length(); m_have_length = true; } return m_length; } bool validate(AllowSurrogates allow_surrogates = AllowSurrogates::Yes) const { size_t valid_bytes = 0; return validate(valid_bytes, allow_surrogates); } bool validate(size_t& valid_bytes, AllowSurrogates allow_surrogates = AllowSurrogates::Yes) const; private: friend class Utf8CodePointIterator; u8 const* begin_ptr() const { return reinterpret_cast(m_string.characters_without_null_termination()); } u8 const* end_ptr() const { return begin_ptr() + m_string.length(); } size_t calculate_length() const; struct Utf8EncodedByteData { size_t byte_length { 0 }; u8 encoding_bits { 0 }; u8 encoding_mask { 0 }; u32 first_code_point { 0 }; u32 last_code_point { 0 }; }; static constexpr Array utf8_encoded_byte_data { { { 1, 0b0000'0000, 0b1000'0000, 0x0000, 0x007F }, { 2, 0b1100'0000, 0b1110'0000, 0x0080, 0x07FF }, { 3, 0b1110'0000, 0b1111'0000, 0x0800, 0xFFFF }, { 4, 0b1111'0000, 0b1111'1000, 0x10000, 0x10FFFF }, } }; struct LeadingByte { size_t byte_length { 0 }; u32 code_point_bits { 0 }; bool is_valid { false }; }; static constexpr LeadingByte decode_leading_byte(u8 byte) { for (auto const& data : utf8_encoded_byte_data) { if ((byte & data.encoding_mask) != data.encoding_bits) continue; byte &= ~data.encoding_mask; return { data.byte_length, byte, true }; } return { .is_valid = false }; } StringView m_string; mutable size_t m_length { 0 }; mutable bool m_have_length { false }; }; class DeprecatedStringCodePointIterator { public: Optional next() { if (m_it.done()) return {}; auto value = *m_it; ++m_it; return value; } [[nodiscard]] Optional peek() const { if (m_it.done()) return {}; return *m_it; } [[nodiscard]] size_t byte_offset() const { return Utf8View(m_string).byte_offset_of(m_it); } DeprecatedStringCodePointIterator(ByteString string) : m_string(move(string)) , m_it(Utf8View(m_string).begin()) { } private: ByteString m_string; Utf8CodePointIterator m_it; }; template<> struct Formatter : Formatter { ErrorOr format(FormatBuilder&, Utf8View const&); }; inline Utf8CodePointIterator& Utf8CodePointIterator::operator++() { VERIFY(m_length > 0); // OPTIMIZATION: Fast path for ASCII characters. if (*m_ptr <= 0x7F) { m_ptr += 1; m_length -= 1; return *this; } size_t code_point_length_in_bytes = underlying_code_point_length_in_bytes(); if (code_point_length_in_bytes > m_length) { // We don't have enough data for the next code point. Skip one character and try again. // The rest of the code will output replacement characters as needed for any eventual extension bytes we might encounter afterwards. dbgln_if(UTF8_DEBUG, "Expected code point size {} is too big for the remaining length {}. Moving forward one byte.", code_point_length_in_bytes, m_length); m_ptr += 1; m_length -= 1; return *this; } m_ptr += code_point_length_in_bytes; m_length -= code_point_length_in_bytes; return *this; } inline size_t Utf8CodePointIterator::underlying_code_point_length_in_bytes() const { VERIFY(m_length > 0); auto [code_point_length_in_bytes, value, first_byte_makes_sense] = Utf8View::decode_leading_byte(*m_ptr); // If any of these tests fail, we will output a replacement character for this byte and treat it as a code point of size 1. if (!first_byte_makes_sense) return 1; if (code_point_length_in_bytes > m_length) return 1; for (size_t offset = 1; offset < code_point_length_in_bytes; offset++) { if (m_ptr[offset] >> 6 != 2) return 1; } return code_point_length_in_bytes; } inline u32 Utf8CodePointIterator::operator*() const { VERIFY(m_length > 0); // OPTIMIZATION: Fast path for ASCII characters. if (*m_ptr <= 0x7F) return *m_ptr; auto [code_point_length_in_bytes, code_point_value_so_far, first_byte_makes_sense] = Utf8View::decode_leading_byte(*m_ptr); if (!first_byte_makes_sense) { // The first byte of the code point doesn't make sense: output a replacement character dbgln_if(UTF8_DEBUG, "First byte doesn't make sense: {:#02x}.", m_ptr[0]); return 0xFFFD; } if (code_point_length_in_bytes > m_length) { // There is not enough data left for the full code point: output a replacement character dbgln_if(UTF8_DEBUG, "Not enough bytes (need {}, have {}), first byte is: {:#02x}.", code_point_length_in_bytes, m_length, m_ptr[0]); return 0xFFFD; } for (size_t offset = 1; offset < code_point_length_in_bytes; offset++) { if (m_ptr[offset] >> 6 != 2) { // One of the extension bytes of the code point doesn't make sense: output a replacement character dbgln_if(UTF8_DEBUG, "Extension byte {:#02x} in {} position after first byte {:#02x} doesn't make sense.", m_ptr[offset], offset, m_ptr[0]); return 0xFFFD; } code_point_value_so_far <<= 6; code_point_value_so_far |= m_ptr[offset] & 63; } if (code_point_value_so_far > 0x10FFFF) { dbgln_if(UTF8_DEBUG, "Multi-byte sequence is otherwise valid, but code point {:#x} is not permissible.", code_point_value_so_far); return 0xFFFD; } return code_point_value_so_far; } } #if USING_AK_GLOBALLY using AK::DeprecatedStringCodePointIterator; using AK::Utf8CodePointIterator; using AK::Utf8View; #endif