core/fxcrt/bytestring.h - pdfium - Git at Google

 // Copyright 2017 PDFium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // Original code copyright 2014 Foxit Software Inc. http://www.foxitsoftware.com

 #ifndef CORE_FXCRT_BYTESTRING_H_
 #define CORE_FXCRT_BYTESTRING_H_

 #include <functional>
 #include <iterator>
 #include <sstream>
 #include <utility>

 #include "core/fxcrt/fx_system.h"
 #include "core/fxcrt/retain_ptr.h"
 #include "core/fxcrt/string_data_template.h"
 #include "core/fxcrt/string_view_template.h"
 #include "third_party/base/optional.h"
 #include "third_party/base/span.h"

 namespace fxcrt {

 class ByteString_Assign_Test;
 class ByteString_Concat_Test;
 class StringPool_ByteString_Test;
 class WideString;

 // A mutable string with shared buffers using copy-on-write semantics that
 // avoids the cost of std::string's iterator stability guarantees.
 class ByteString {
  public:
   using CharType = char;
   using const_iterator = const CharType*;
   using const_reverse_iterator = std::reverse_iterator<const_iterator>;

   static ByteString FormatInteger(int i) WARN_UNUSED_RESULT;
   static ByteString FormatFloat(float f) WARN_UNUSED_RESULT;
   static ByteString Format(const char* lpszFormat, ...) WARN_UNUSED_RESULT;
   static ByteString FormatV(const char* lpszFormat,
                             va_list argList) WARN_UNUSED_RESULT;

   ByteString();
   ByteString(const ByteString& other);
   ByteString(ByteString&& other) noexcept;

   // Deliberately implicit to avoid calling on every string literal.
   // NOLINTNEXTLINE(runtime/explicit)
   ByteString(char ch);
   // NOLINTNEXTLINE(runtime/explicit)
   ByteString(const char* ptr);

   // No implicit conversions from wide strings.
   // NOLINTNEXTLINE(runtime/explicit)
   ByteString(wchar_t) = delete;

   ByteString(const char* ptr, size_t len);
   ByteString(const uint8_t* ptr, size_t len);

   explicit ByteString(const ByteStringView& bstrc);
   ByteString(const ByteStringView& bstrc1, const ByteStringView& bstrc2);
   ByteString(const std::initializer_list<ByteStringView>& list);
   explicit ByteString(const std::ostringstream& outStream);

   ~ByteString();

   void clear() { m_pData.Reset(); }

   // Explicit conversion to C-style string.
   // Note: Any subsequent modification of |this| will invalidate the result.
   const char* c_str() const { return m_pData ? m_pData->m_String : ""; }

   // Explicit conversion to uint8_t*.
   // Note: Any subsequent modification of |this| will invalidate the result.
   const uint8_t* raw_str() const {
     return m_pData ? reinterpret_cast<const uint8_t*>(m_pData->m_String)
                    : nullptr;
   }

   // Explicit conversion to ByteStringView.
   // Note: Any subsequent modification of |this| will invalidate the result.
   ByteStringView AsStringView() const {
     return ByteStringView(raw_str(), GetLength());
   }

   // Explicit conversion to span.
   // Note: Any subsequent modification of |this| will invalidate the result.
   pdfium::span<const char> AsSpan() const {
     return pdfium::make_span(m_pData ? m_pData->m_String : nullptr,
                              GetLength());
   }
   pdfium::span<const uint8_t> AsRawSpan() const {
     return pdfium::make_span(raw_str(), GetLength());
   }

   // Note: Any subsequent modification of |this| will invalidate iterators.
   const_iterator begin() const { return m_pData ? m_pData->m_String : nullptr; }
   const_iterator end() const {
     return m_pData ? m_pData->m_String + m_pData->m_nDataLength : nullptr;
   }

   // Note: Any subsequent modification of |this| will invalidate iterators.
   const_reverse_iterator rbegin() const {
     return const_reverse_iterator(end());
   }
   const_reverse_iterator rend() const {
     return const_reverse_iterator(begin());
   }

   size_t GetLength() const { return m_pData ? m_pData->m_nDataLength : 0; }
   size_t GetStringLength() const {
     return m_pData ? strlen(m_pData->m_String) : 0;
   }
   bool IsEmpty() const { return !GetLength(); }
   bool IsValidIndex(size_t index) const { return index < GetLength(); }
   bool IsValidLength(size_t length) const { return length <= GetLength(); }

   int Compare(const ByteStringView& str) const;
   bool EqualNoCase(const ByteStringView& str) const;

   bool operator==(const char* ptr) const;
   bool operator==(const ByteStringView& str) const;
   bool operator==(const ByteString& other) const;

   bool operator!=(const char* ptr) const { return !(*this == ptr); }
   bool operator!=(const ByteStringView& str) const { return !(*this == str); }
   bool operator!=(const ByteString& other) const { return !(*this == other); }

   bool operator<(const char* ptr) const;
   bool operator<(const ByteStringView& str) const;
   bool operator<(const ByteString& other) const;

   const ByteString& operator=(const char* str);
   const ByteString& operator=(const ByteStringView& bstrc);
   const ByteString& operator=(const ByteString& that);
   const ByteString& operator=(ByteString&& that);

   const ByteString& operator+=(char ch);
   const ByteString& operator+=(const char* str);
   const ByteString& operator+=(const ByteString& str);
   const ByteString& operator+=(const ByteStringView& bstrc);

   CharType operator[](const size_t index) const {
     ASSERT(IsValidIndex(index));
     return m_pData ? m_pData->m_String[index] : 0;
   }

   CharType First() const { return GetLength() ? (*this)[0] : 0; }
   CharType Last() const { return GetLength() ? (*this)[GetLength() - 1] : 0; }

   void SetAt(size_t index, char c);

   size_t Insert(size_t index, char ch);
   size_t InsertAtFront(char ch) { return Insert(0, ch); }
   size_t InsertAtBack(char ch) { return Insert(GetLength(), ch); }
   size_t Delete(size_t index, size_t count = 1);

   void Reserve(size_t len);

   // Note: any modification of the string (including ReleaseBuffer()) may
   // invalidate the span, which must not outlive its buffer.
   pdfium::span<char> GetBuffer(size_t len);
   void ReleaseBuffer(size_t len);

   ByteString Mid(size_t first, size_t count) const;
   ByteString Left(size_t count) const;
   ByteString Right(size_t count) const;

   Optional<size_t> Find(const ByteStringView& lpszSub, size_t start = 0) const;
   Optional<size_t> Find(char ch, size_t start = 0) const;
   Optional<size_t> ReverseFind(char ch) const;

   bool Contains(const ByteStringView& lpszSub, size_t start = 0) const {
     return Find(lpszSub, start).has_value();
   }

   bool Contains(char ch, size_t start = 0) const {
     return Find(ch, start).has_value();
   }

   void MakeLower();
   void MakeUpper();

   void Trim();
   void Trim(char target);
   void Trim(const ByteStringView& targets);

   void TrimLeft();
   void TrimLeft(char target);
   void TrimLeft(const ByteStringView& targets);

   void TrimRight();
   void TrimRight(char target);
   void TrimRight(const ByteStringView& targets);

   size_t Replace(const ByteStringView& lpszOld, const ByteStringView& lpszNew);

   size_t Remove(char ch);

   WideString UTF8Decode() const;

   uint32_t GetID() const { return AsStringView().GetID(); }

  protected:
   using StringData = StringDataTemplate<char>;

   void ReallocBeforeWrite(size_t nNewLen);
   void AllocBeforeWrite(size_t nNewLen);
   void AllocCopy(ByteString& dest, size_t nCopyLen, size_t nCopyIndex) const;
   void AssignCopy(const char* pSrcData, size_t nSrcLen);
   void Concat(const char* lpszSrcData, size_t nSrcLen);
   intptr_t ReferenceCountForTesting() const;

   RetainPtr<StringData> m_pData;

   friend ByteString_Assign_Test;
   friend ByteString_Concat_Test;
   friend class StringPool_ByteString_Test;
 };

 inline bool operator==(const char* lhs, const ByteString& rhs) {
   return rhs == lhs;
 }
 inline bool operator==(const ByteStringView& lhs, const ByteString& rhs) {
   return rhs == lhs;
 }
 inline bool operator!=(const char* lhs, const ByteString& rhs) {
   return rhs != lhs;
 }
 inline bool operator!=(const ByteStringView& lhs, const ByteString& rhs) {
   return rhs != lhs;
 }
 inline bool operator<(const char* lhs, const ByteString& rhs) {
   return rhs.Compare(lhs) > 0;
 }

 inline ByteString operator+(const ByteStringView& str1,
                             const ByteStringView& str2) {
   return ByteString(str1, str2);
 }
 inline ByteString operator+(const ByteStringView& str1, const char* str2) {
   return ByteString(str1, str2);
 }
 inline ByteString operator+(const char* str1, const ByteStringView& str2) {
   return ByteString(str1, str2);
 }
 inline ByteString operator+(const ByteStringView& str1, char ch) {
   return ByteString(str1, ByteStringView(ch));
 }
 inline ByteString operator+(char ch, const ByteStringView& str2) {
   return ByteString(ch, str2);
 }
 inline ByteString operator+(const ByteString& str1, const ByteString& str2) {
   return ByteString(str1.AsStringView(), str2.AsStringView());
 }
 inline ByteString operator+(const ByteString& str1, char ch) {
   return ByteString(str1.AsStringView(), ByteStringView(ch));
 }
 inline ByteString operator+(char ch, const ByteString& str2) {
   return ByteString(ch, str2.AsStringView());
 }
 inline ByteString operator+(const ByteString& str1, const char* str2) {
   return ByteString(str1.AsStringView(), str2);
 }
 inline ByteString operator+(const char* str1, const ByteString& str2) {
   return ByteString(str1, str2.AsStringView());
 }
 inline ByteString operator+(const ByteString& str1,
                             const ByteStringView& str2) {
   return ByteString(str1.AsStringView(), str2);
 }
 inline ByteString operator+(const ByteStringView& str1,
                             const ByteString& str2) {
   return ByteString(str1, str2.AsStringView());
 }

 std::ostream& operator<<(std::ostream& os, const ByteString& str);
 std::ostream& operator<<(std::ostream& os, const ByteStringView& str);

 }  // namespace fxcrt

 using ByteString = fxcrt::ByteString;

 uint32_t FX_HashCode_GetA(const ByteStringView& str, bool bIgnoreCase);

 namespace std {

 template <>
 struct hash<ByteString> {
   std::size_t operator()(const ByteString& str) const {
     return FX_HashCode_GetA(str.AsStringView(), false);
   }
 };

 }  // namespace std

 extern template struct std::hash<ByteString>;

 #endif  // CORE_FXCRT_BYTESTRING_H_
	// Copyright 2017 PDFium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// Original code copyright 2014 Foxit Software Inc. http://www.foxitsoftware.com

	#ifndef CORE_FXCRT_BYTESTRING_H_
	#define CORE_FXCRT_BYTESTRING_H_

	#include <functional>
	#include <iterator>
	#include <sstream>
	#include <utility>

	#include "core/fxcrt/fx_system.h"
	#include "core/fxcrt/retain_ptr.h"
	#include "core/fxcrt/string_data_template.h"
	#include "core/fxcrt/string_view_template.h"
	#include "third_party/base/optional.h"
	#include "third_party/base/span.h"

	namespace fxcrt {

	class ByteString_Assign_Test;
	class ByteString_Concat_Test;
	class StringPool_ByteString_Test;
	class WideString;

	// A mutable string with shared buffers using copy-on-write semantics that
	// avoids the cost of std::string's iterator stability guarantees.
	class ByteString {
	public:
	using CharType = char;
	using const_iterator = const CharType*;
	using const_reverse_iterator = std::reverse_iterator<const_iterator>;

	static ByteString FormatInteger(int i) WARN_UNUSED_RESULT;
	static ByteString FormatFloat(float f) WARN_UNUSED_RESULT;
	static ByteString Format(const char* lpszFormat, ...) WARN_UNUSED_RESULT;
	static ByteString FormatV(const char* lpszFormat,
	va_list argList) WARN_UNUSED_RESULT;

	ByteString();
	ByteString(const ByteString& other);
	ByteString(ByteString&& other) noexcept;

	// Deliberately implicit to avoid calling on every string literal.
	// NOLINTNEXTLINE(runtime/explicit)
	ByteString(char ch);
	// NOLINTNEXTLINE(runtime/explicit)
	ByteString(const char* ptr);

	// No implicit conversions from wide strings.
	// NOLINTNEXTLINE(runtime/explicit)
	ByteString(wchar_t) = delete;

	ByteString(const char* ptr, size_t len);
	ByteString(const uint8_t* ptr, size_t len);

	explicit ByteString(const ByteStringView& bstrc);
	ByteString(const ByteStringView& bstrc1, const ByteStringView& bstrc2);
	ByteString(const std::initializer_list<ByteStringView>& list);
	explicit ByteString(const std::ostringstream& outStream);

	~ByteString();

	void clear() { m_pData.Reset(); }

	// Explicit conversion to C-style string.
	// Note: Any subsequent modification of \|this\| will invalidate the result.
	const char* c_str() const { return m_pData ? m_pData->m_String : ""; }

	// Explicit conversion to uint8_t*.
	// Note: Any subsequent modification of \|this\| will invalidate the result.
	const uint8_t* raw_str() const {
	return m_pData ? reinterpret_cast<const uint8_t*>(m_pData->m_String)
	: nullptr;
	}

	// Explicit conversion to ByteStringView.
	// Note: Any subsequent modification of \|this\| will invalidate the result.
	ByteStringView AsStringView() const {
	return ByteStringView(raw_str(), GetLength());
	}

	// Explicit conversion to span.
	// Note: Any subsequent modification of \|this\| will invalidate the result.
	pdfium::span<const char> AsSpan() const {
	return pdfium::make_span(m_pData ? m_pData->m_String : nullptr,
	GetLength());
	}
	pdfium::span<const uint8_t> AsRawSpan() const {
	return pdfium::make_span(raw_str(), GetLength());
	}

	// Note: Any subsequent modification of \|this\| will invalidate iterators.
	const_iterator begin() const { return m_pData ? m_pData->m_String : nullptr; }
	const_iterator end() const {
	return m_pData ? m_pData->m_String + m_pData->m_nDataLength : nullptr;
	}

	// Note: Any subsequent modification of \|this\| will invalidate iterators.
	const_reverse_iterator rbegin() const {
	return const_reverse_iterator(end());
	}
	const_reverse_iterator rend() const {
	return const_reverse_iterator(begin());
	}

	size_t GetLength() const { return m_pData ? m_pData->m_nDataLength : 0; }
	size_t GetStringLength() const {
	return m_pData ? strlen(m_pData->m_String) : 0;
	}
	bool IsEmpty() const { return !GetLength(); }
	bool IsValidIndex(size_t index) const { return index < GetLength(); }
	bool IsValidLength(size_t length) const { return length <= GetLength(); }

	int Compare(const ByteStringView& str) const;
	bool EqualNoCase(const ByteStringView& str) const;

	bool operator==(const char* ptr) const;
	bool operator==(const ByteStringView& str) const;
	bool operator==(const ByteString& other) const;

	bool operator!=(const char* ptr) const { return !(*this == ptr); }
	bool operator!=(const ByteStringView& str) const { return !(*this == str); }
	bool operator!=(const ByteString& other) const { return !(*this == other); }

	bool operator<(const char* ptr) const;
	bool operator<(const ByteStringView& str) const;
	bool operator<(const ByteString& other) const;

	const ByteString& operator=(const char* str);
	const ByteString& operator=(const ByteStringView& bstrc);
	const ByteString& operator=(const ByteString& that);
	const ByteString& operator=(ByteString&& that);

	const ByteString& operator+=(char ch);
	const ByteString& operator+=(const char* str);
	const ByteString& operator+=(const ByteString& str);
	const ByteString& operator+=(const ByteStringView& bstrc);

	CharType operator[](const size_t index) const {
	ASSERT(IsValidIndex(index));
	return m_pData ? m_pData->m_String[index] : 0;
	}

	CharType First() const { return GetLength() ? (*this)[0] : 0; }
	CharType Last() const { return GetLength() ? (*this)[GetLength() - 1] : 0; }

	void SetAt(size_t index, char c);

	size_t Insert(size_t index, char ch);
	size_t InsertAtFront(char ch) { return Insert(0, ch); }
	size_t InsertAtBack(char ch) { return Insert(GetLength(), ch); }
	size_t Delete(size_t index, size_t count = 1);

	void Reserve(size_t len);

	// Note: any modification of the string (including ReleaseBuffer()) may
	// invalidate the span, which must not outlive its buffer.
	pdfium::span<char> GetBuffer(size_t len);
	void ReleaseBuffer(size_t len);

	ByteString Mid(size_t first, size_t count) const;
	ByteString Left(size_t count) const;
	ByteString Right(size_t count) const;

	Optional<size_t> Find(const ByteStringView& lpszSub, size_t start = 0) const;
	Optional<size_t> Find(char ch, size_t start = 0) const;
	Optional<size_t> ReverseFind(char ch) const;

	bool Contains(const ByteStringView& lpszSub, size_t start = 0) const {
	return Find(lpszSub, start).has_value();
	}

	bool Contains(char ch, size_t start = 0) const {
	return Find(ch, start).has_value();
	}

	void MakeLower();
	void MakeUpper();

	void Trim();
	void Trim(char target);
	void Trim(const ByteStringView& targets);

	void TrimLeft();
	void TrimLeft(char target);
	void TrimLeft(const ByteStringView& targets);

	void TrimRight();
	void TrimRight(char target);
	void TrimRight(const ByteStringView& targets);

	size_t Replace(const ByteStringView& lpszOld, const ByteStringView& lpszNew);

	size_t Remove(char ch);

	WideString UTF8Decode() const;

	uint32_t GetID() const { return AsStringView().GetID(); }

	protected:
	using StringData = StringDataTemplate<char>;

	void ReallocBeforeWrite(size_t nNewLen);
	void AllocBeforeWrite(size_t nNewLen);
	void AllocCopy(ByteString& dest, size_t nCopyLen, size_t nCopyIndex) const;
	void AssignCopy(const char* pSrcData, size_t nSrcLen);
	void Concat(const char* lpszSrcData, size_t nSrcLen);
	intptr_t ReferenceCountForTesting() const;

	RetainPtr<StringData> m_pData;

	friend ByteString_Assign_Test;
	friend ByteString_Concat_Test;
	friend class StringPool_ByteString_Test;
	};

	inline bool operator==(const char* lhs, const ByteString& rhs) {
	return rhs == lhs;
	}
	inline bool operator==(const ByteStringView& lhs, const ByteString& rhs) {
	return rhs == lhs;
	}
	inline bool operator!=(const char* lhs, const ByteString& rhs) {
	return rhs != lhs;
	}
	inline bool operator!=(const ByteStringView& lhs, const ByteString& rhs) {
	return rhs != lhs;
	}
	inline bool operator<(const char* lhs, const ByteString& rhs) {
	return rhs.Compare(lhs) > 0;
	}

	inline ByteString operator+(const ByteStringView& str1,
	const ByteStringView& str2) {
	return ByteString(str1, str2);
	}
	inline ByteString operator+(const ByteStringView& str1, const char* str2) {
	return ByteString(str1, str2);
	}
	inline ByteString operator+(const char* str1, const ByteStringView& str2) {
	return ByteString(str1, str2);
	}
	inline ByteString operator+(const ByteStringView& str1, char ch) {
	return ByteString(str1, ByteStringView(ch));
	}
	inline ByteString operator+(char ch, const ByteStringView& str2) {
	return ByteString(ch, str2);
	}
	inline ByteString operator+(const ByteString& str1, const ByteString& str2) {
	return ByteString(str1.AsStringView(), str2.AsStringView());
	}
	inline ByteString operator+(const ByteString& str1, char ch) {
	return ByteString(str1.AsStringView(), ByteStringView(ch));
	}
	inline ByteString operator+(char ch, const ByteString& str2) {
	return ByteString(ch, str2.AsStringView());
	}
	inline ByteString operator+(const ByteString& str1, const char* str2) {
	return ByteString(str1.AsStringView(), str2);
	}
	inline ByteString operator+(const char* str1, const ByteString& str2) {
	return ByteString(str1, str2.AsStringView());
	}
	inline ByteString operator+(const ByteString& str1,
	const ByteStringView& str2) {
	return ByteString(str1.AsStringView(), str2);
	}
	inline ByteString operator+(const ByteStringView& str1,
	const ByteString& str2) {
	return ByteString(str1, str2.AsStringView());
	}

	std::ostream& operator<<(std::ostream& os, const ByteString& str);
	std::ostream& operator<<(std::ostream& os, const ByteStringView& str);

	} // namespace fxcrt

	using ByteString = fxcrt::ByteString;

	uint32_t FX_HashCode_GetA(const ByteStringView& str, bool bIgnoreCase);

	namespace std {

	template <>
	struct hash<ByteString> {
	std::size_t operator()(const ByteString& str) const {
	return FX_HashCode_GetA(str.AsStringView(), false);
	}
	};

	} // namespace std

	extern template struct std::hash<ByteString>;

	#endif // CORE_FXCRT_BYTESTRING_H_