/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* * This file is part of the LibreOffice project. * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #ifndef INCLUDED_RTL_STRINGCONCAT_HXX #define INCLUDED_RTL_STRINGCONCAT_HXX // This file is only included from LIBO_INTERNAL_ONLY #include "rtl/stringutils.hxx" #include "rtl/string.h" #include "rtl/ustring.h" #include #include #include #include #include #include #include #include #if defined RTL_STRING_UNITTEST_CONCAT extern bool rtl_string_unittest_invalid_concat; #endif #ifdef RTL_STRING_UNITTEST #define rtl rtlunittest #endif namespace rtl { #ifdef RTL_STRING_UNITTEST #undef rtl #endif /* Implementation of efficient string concatenation. The whole system is built around two basic template classes: - ToStringHelper< T > - for each T it can give the length of the resulting string representation and can write this string representation to a buffer - O(U)StringConcat< T1, T2 > - operator+ now, instead of creating O(U)String object, returns only this helper object, that keeps a reference to both operator+ operands; only when converted to O(U)String it will actually create the resulting string object using ToStringHelper, creating directly the resulting object without any string intermediate objects As all the code is inline methods, it allows for extensive optimization and will usually result in very effective code (even surpassing strlen/strcat and equalling handwritten), while allowing for very easy and intuitive syntax. */ /** @internal Helper class for converting a given type to a string representation. */ template< typename T > struct ToStringHelper { /// Return length of the string representation of the given object. // static std::size_t length( const T& ); /// Add 8-bit representation of the given object to the given buffer and return position right after the added data. // char* operator()( char* buffer, const T& ) const SAL_RETURNS_NONNULL; /// Add Unicode representation of the given object to the given buffer and return position right after the added data. // sal_Unicode* operator()( sal_Unicode* buffer, const T& ) const SAL_RETURNS_NONNULL; }; /// If true, T can be used in concatenation resulting in O(U)String. template constexpr bool allowStringConcat = false; template constexpr bool allowStringConcat, C*, T>>> = true; template inline C* addDataHelper( C* buffer, const C* data, std::size_t length ) { if (length != 0) { memcpy( buffer, data, length * sizeof( C )); } return buffer + length; } inline sal_Unicode* addDataLiteral( sal_Unicode* buffer, const char* data, std::size_t length ) { for( std::size_t i = 0; i != length; ++i ) *buffer++ = *data++; return buffer; } template inline C* addDataString( C* buffer, const C* str ) { while( *str != '\0' ) *buffer++ = *str++; return buffer; } template<> struct ToStringHelper< const char* > { static std::size_t length( const char* str ) { return str ? strlen( str ) : 0; } char* operator()( char* buffer, const char* str ) const { return str ? addDataString( buffer, str ) : buffer; } }; template<> struct ToStringHelper< char* > : public ToStringHelper< const char* > {}; template< std::size_t N > struct ToStringHelper< char[ N ] > { static std::size_t length( const char str[ N ] ) { return strlen( str ); } char* operator()( char* buffer, const char str[ N ] ) const { return addDataString( buffer, str ); } }; template< std::size_t N > struct ToStringHelper< const char[ N ] > { static std::size_t length( const char str[ N ] ) { (void)str; assert( strlen( str ) == N - 1 ); return N - 1; } char* operator()( char* buffer, const char str[ N ] ) const { return addDataHelper( buffer, str, N - 1 ); } sal_Unicode* operator()( sal_Unicode* buffer, const char str[ N ] ) const { return addDataLiteral( buffer, str, N - 1 ); } }; template<> struct ToStringHelper { static std::size_t length(OStringChar) { return 1; } char* operator()(char* buffer, OStringChar data) const { return addDataHelper(buffer, &data.c, 1); } }; template<> struct ToStringHelper< const sal_Unicode* > { static std::size_t length( const sal_Unicode* str ) { return str ? std::char_traits::length( str ) : 0; } sal_Unicode* operator()( sal_Unicode* buffer, const sal_Unicode* str ) const { return str ? addDataString( buffer, str ) : buffer; } }; template<> struct ToStringHelper< sal_Unicode* > : public ToStringHelper< const sal_Unicode* > {}; template struct ToStringHelper { static std::size_t length( const sal_Unicode str[ N ] ) { return std::char_traits::length( str ); } sal_Unicode * operator()(sal_Unicode * buffer, sal_Unicode const str[N]) const { return addDataHelper(buffer, str, N - 1); } }; template struct ToStringHelper { static std::size_t length( const sal_Unicode str[ N ] ) { (void)str; assert( std::char_traits::length( str ) == N - 1 ); return N - 1; } sal_Unicode * operator()(sal_Unicode * buffer, sal_Unicode const str[N]) const { return addDataHelper(buffer, str, N - 1); } }; template<> struct ToStringHelper { static std::size_t length(OUStringChar_) { return 1; } sal_Unicode * operator()(sal_Unicode * buffer, OUStringChar_ literal) const { return addDataHelper(buffer, &literal.c, 1); } }; /** @internal Objects returned by operator+, instead of O(U)String. These objects (possibly recursively) keep a representation of the whole concatenation operation. If you get a build error related to this class, you most probably need to explicitly convert the result of a string concatenation to O(U)String. */ template && allowStringConcat, int> = 0 > struct StringConcat { public: StringConcat( const T1& left_, const T2& right_ ) : left( left_ ), right( right_ ) {} std::size_t length() const { return ToStringHelper< T1 >::length( left ) + ToStringHelper< T2 >::length( right ); } C* addData( C* buffer ) const SAL_RETURNS_NONNULL { return ToStringHelper< T2 >()( ToStringHelper< T1 >()( buffer, left ), right ); } // NOTE here could be functions that would forward to the "real" temporary O(U)String. Note however that e.g. getStr() // is not so simple, as the O(U)String temporary must live long enough (i.e. can't be created here in a function, a wrapper // temporary object containing it must be returned instead). private: const T1& left; const T2& right; }; template struct ToStringHelper> { static std::size_t length(const StringConcat& c) { return c.length(); } C* operator()(C* buffer, const StringConcat& c) const SAL_RETURNS_NONNULL { return c.addData(buffer); } }; template using OStringConcat = StringConcat; template using OUStringConcat = StringConcat; template< typename T1, typename T2 > [[nodiscard]] inline OStringConcat< T1, T2 > operator+( const T1& left, const T2& right ) { return OStringConcat< T1, T2 >( left, right ); } // char[N] and const char[N] need to be done explicitly, otherwise the compiler likes to treat them the same way for some reason template< typename T, std::size_t N > [[nodiscard]] inline OStringConcat< T, const char[ N ] > operator+( const T& left, const char (&right)[ N ] ) { return OStringConcat< T, const char[ N ] >( left, right ); } template< typename T, std::size_t N > [[nodiscard]] inline OStringConcat< const char[ N ], T > operator+( const char (&left)[ N ], const T& right ) { return OStringConcat< const char[ N ], T >( left, right ); } template< typename T, std::size_t N > [[nodiscard]] inline OStringConcat< T, char[ N ] > operator+( const T& left, char (&right)[ N ] ) { return OStringConcat< T, char[ N ] >( left, right ); } template< typename T, std::size_t N > [[nodiscard]] inline OStringConcat< char[ N ], T > operator+( char (&left)[ N ], const T& right ) { return OStringConcat< char[ N ], T >( left, right ); } template< typename T1, typename T2 > [[nodiscard]] inline OUStringConcat< T1, T2 > operator+( const T1& left, const T2& right ) { return OUStringConcat< T1, T2 >( left, right ); } template< typename T1, typename T2 > [[nodiscard]] inline typename std::enable_if_t< libreoffice_internal::ConstCharArrayDetector< T1, void >::ok, OUStringConcat< T1, T2 > > operator+( T1& left, const T2& right ) { return OUStringConcat< T1, T2 >( left, right ); } template< typename T1, typename T2 > [[nodiscard]] inline typename std::enable_if_t< libreoffice_internal::ConstCharArrayDetector< T2, void >::ok, OUStringConcat< T1, T2 > > operator+( const T1& left, T2& right ) { return OUStringConcat< T1, T2 >( left, right ); } #ifdef RTL_STRING_UNITTEST_CONCAT // Special overload to catch the remaining invalid combinations. The helper struct must // be used to make this operator+ overload a worse choice than all the existing overloads above. struct StringConcatInvalid { template< typename T > StringConcatInvalid( const T& ) {} }; template< typename T > inline int operator+( const StringConcatInvalid&, const T& ) { rtl_string_unittest_invalid_concat = true; return 0; // doesn't matter } #endif // Lightweight alternative to O(U)String when a (temporary) object is needed to hold // an O(U)StringConcat result that can then be used as a std::(u16)string_view: template class StringConcatenation { public: template explicit StringConcatenation(Concat const& c): length_(c.length()), buffer_(new C[length_]) { auto const end = c.addData(buffer_.get()); assert(end == buffer_.get() + length_); (void)end; } operator std::basic_string_view() const { return {buffer_.get(), length_}; } private: std::size_t length_; std::unique_ptr buffer_; }; template auto Concat2View(OStringConcat const& c) { return StringConcatenation(c); } template auto Concat2View(OUStringConcat const& c) { return StringConcatenation(c); } /** * O(U)StringNumber implementation Objects returned by O(U)String::number(), instead of O(U)String. These objects keep a representation of the number() operation. If you get a build error related to this class, you most probably need to explicitly convert the result of calling O(U)String::number() to O(U)String. */ template struct StringNumber { template , int> = 0> StringNumber(Func func, Args... args) { length = func(buf, args...); } // O(U)String::number(value).getStr() is very common (writing xml code, ...), // so implement that one also here, to avoid having to explicitly convert // to O(U)String in all such places const C* getStr() const SAL_RETURNS_NONNULL { return buf; } StringNumber&& toAsciiUpperCase() && { if constexpr (sizeof(C) == sizeof(char)) rtl_str_toAsciiUpperCase_WithLength(buf, length); else rtl_ustr_toAsciiUpperCase_WithLength(buf, length); return std::move(*this); } operator std::basic_string_view() const { return std::basic_string_view(buf, length); } C buf[nBufSize]; sal_Int32 length; }; template using OStringNumber = StringNumber; template using OUStringNumber = StringNumber; template< typename C, std::size_t nBufSize > struct ToStringHelper< StringNumber< C, nBufSize > > { static std::size_t length( const StringNumber< C, nBufSize >& n ) { return n.length; } C* operator()( C* buffer, const StringNumber< C, nBufSize >& n ) const SAL_RETURNS_NONNULL { return addDataHelper( buffer, n.buf, n.length ); } }; template struct ToStringHelper> { static constexpr std::size_t length(std::basic_string_view s) { return s.size(); } C * operator()(C * buffer, std::basic_string_view s) const SAL_RETURNS_NONNULL { return addDataHelper(buffer, s.data(), s.size()); } }; // An internal marker class used by O(U)String::Concat: template struct StringConcatMarker {}; using OStringConcatMarker = StringConcatMarker; using OUStringConcatMarker = StringConcatMarker; template constexpr bool allowStringConcat> = true; #if defined __GNUC__ && !defined __clang__ template struct StringConcat, T2> #else template , int> Dummy> struct StringConcat, T2, Dummy> #endif { public: StringConcat( const T2& right_ ) : right( right_ ) {} std::size_t length() const { return ToStringHelper< T2 >::length( right ); } C* addData( C* buffer ) const SAL_RETURNS_NONNULL { return ToStringHelper< T2 >()( buffer, right ); } private: const T2& right; }; } // namespace #endif