// Copyright 2013 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef BASE_STRINGS_STRING16_H_ #define BASE_STRINGS_STRING16_H_ // WHAT: // A version of std::basic_string that provides 2-byte characters even when // wchar_t is not implemented as a 2-byte type. You can access this class as // string16. We also define char16, which string16 is based upon. // // WHY: // On Windows, wchar_t is 2 bytes, and it can conveniently handle UTF-16/UCS-2 // data. Plenty of existing code operates on strings encoded as UTF-16. // // On many other platforms, sizeof(wchar_t) is 4 bytes by default. We can make // it 2 bytes by using the GCC flag -fshort-wchar. But then std::wstring fails // at run time, because it calls some functions (like wcslen) that come from // the system's native C library -- which was built with a 4-byte wchar_t! // It's wasteful to use 4-byte wchar_t strings to carry UTF-16 data, and it's // entirely improper on those systems where the encoding of wchar_t is defined // as UTF-32. // // Here, we define string16, which is similar to std::wstring but replaces all // libc functions with custom, 2-byte-char compatible routines. It is capable // of carrying UTF-16-encoded data. #include #include #include #include #include #include "base/base_export.h" #include "build/build_config.h" #if defined(WCHAR_T_IS_UTF16) // Define a macro for wrapping construction of char16 arrays and string16s from // a literal string. This indirection allows for an easier migration of // base::char16 to char16_t on platforms where WCHAR_T_IS_UTF16, as only a one // character change to the macro will be necessary. // This macro does not exist when WCHAR_T_IS_UTF32, as it is currently not // possible to create a char array form a literal in this case. // TODO(https://crbug.com/911896): Remove this macro once base::char16 is // char16_t on all platforms. #define STRING16_LITERAL(x) L##x namespace base { typedef wchar_t char16; typedef std::wstring string16; } // namespace base #elif defined(WCHAR_T_IS_UTF32) #include // for mbstate_t namespace base { typedef uint16_t char16; // char16 versions of the functions required by string16_char_traits; these // are based on the wide character functions of similar names ("w" or "wcs" // instead of "c16"). BASE_EXPORT int c16memcmp(const char16* s1, const char16* s2, size_t n); BASE_EXPORT size_t c16len(const char16* s); BASE_EXPORT const char16* c16memchr(const char16* s, char16 c, size_t n); BASE_EXPORT char16* c16memmove(char16* s1, const char16* s2, size_t n); BASE_EXPORT char16* c16memcpy(char16* s1, const char16* s2, size_t n); BASE_EXPORT char16* c16memset(char16* s, char16 c, size_t n); // This namespace contains the implementation of base::string16 along with // things that need to be found via argument-dependent lookup from a // base::string16. namespace string16_internals { struct string16_char_traits { typedef char16 char_type; typedef int int_type; // int_type needs to be able to hold each possible value of char_type, and in // addition, the distinct value of eof(). static_assert(sizeof(int_type) > sizeof(char_type), "int must be larger than 16 bits wide"); typedef std::streamoff off_type; typedef mbstate_t state_type; typedef std::fpos pos_type; static void assign(char_type& c1, const char_type& c2) { c1 = c2; } static bool eq(const char_type& c1, const char_type& c2) { return c1 == c2; } static bool lt(const char_type& c1, const char_type& c2) { return c1 < c2; } static int compare(const char_type* s1, const char_type* s2, size_t n) { return c16memcmp(s1, s2, n); } static size_t length(const char_type* s) { return c16len(s); } static const char_type* find(const char_type* s, size_t n, const char_type& a) { return c16memchr(s, a, n); } static char_type* move(char_type* s1, const char_type* s2, size_t n) { return c16memmove(s1, s2, n); } static char_type* copy(char_type* s1, const char_type* s2, size_t n) { return c16memcpy(s1, s2, n); } static char_type* assign(char_type* s, size_t n, char_type a) { return c16memset(s, a, n); } static int_type not_eof(const int_type& c) { return eq_int_type(c, eof()) ? 0 : c; } static char_type to_char_type(const int_type& c) { return char_type(c); } static int_type to_int_type(const char_type& c) { return int_type(c); } static bool eq_int_type(const int_type& c1, const int_type& c2) { return c1 == c2; } static int_type eof() { return static_cast(EOF); } }; } // namespace string16_internals typedef std::basic_string string16; namespace string16_internals { BASE_EXPORT extern std::ostream& operator<<(std::ostream& out, const string16& str); // This is required by googletest to print a readable output on test failures. BASE_EXPORT extern void PrintTo(const string16& str, std::ostream* out); } // namespace string16_internals } // namespace base // The string class will be explicitly instantiated only once, in string16.cc. // // std::basic_string<> in GNU libstdc++ contains a static data member, // _S_empty_rep_storage, to represent empty strings. When an operation such // as assignment or destruction is performed on a string, causing its existing // data member to be invalidated, it must not be freed if this static data // member is being used. Otherwise, it counts as an attempt to free static // (and not allocated) data, which is a memory error. // // Generally, due to C++ template magic, _S_empty_rep_storage will be marked // as a coalesced symbol, meaning that the linker will combine multiple // instances into a single one when generating output. // // If a string class is used by multiple shared libraries, a problem occurs. // Each library will get its own copy of _S_empty_rep_storage. When strings // are passed across a library boundary for alteration or destruction, memory // errors will result. GNU libstdc++ contains a configuration option, // --enable-fully-dynamic-string (_GLIBCXX_FULLY_DYNAMIC_STRING), which // disables the static data member optimization, but it's a good optimization // and non-STL code is generally at the mercy of the system's STL // configuration. Fully-dynamic strings are not the default for GNU libstdc++ // libstdc++ itself or for the libstdc++ installations on the systems we care // about, such as Mac OS X and relevant flavors of Linux. // // See also http://gcc.gnu.org/bugzilla/show_bug.cgi?id=24196 . // // To avoid problems, string classes need to be explicitly instantiated only // once, in exactly one library. All other string users see it via an "extern" // declaration. This is precisely how GNU libstdc++ handles // std::basic_string (string) and std::basic_string (wstring). // // This also works around a Mac OS X linker bug in ld64-85.2.1 (Xcode 3.1.2), // in which the linker does not fully coalesce symbols when dead code // stripping is enabled. This bug causes the memory errors described above // to occur even when a std::basic_string<> does not cross shared library // boundaries, such as in statically-linked executables. // // TODO(mark): File this bug with Apple and update this note with a bug number. extern template class BASE_EXPORT std::basic_string; // Specialize std::hash for base::string16. Although the style guide forbids // this in general, it is necessary for consistency with WCHAR_T_IS_UTF16 // platforms, where base::string16 is a type alias for std::wstring. namespace std { template <> struct hash { std::size_t operator()(const base::string16& s) const { std::size_t result = 0; for (base::char16 c : s) result = (result * 131) + c; return result; } }; } // namespace std #endif // WCHAR_T_IS_UTF32 #endif // BASE_STRINGS_STRING16_H_