/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim:set ts=2 sw=2 sts=2 et cindent: */ /* 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/. */ // IWYU pragma: private, include "nsString.h" /** * This is the canonical null-terminated string class. All subclasses * promise null-terminated storage. Instances of this class allocate * strings on the heap. * * NAMES: * nsString for wide characters * nsCString for narrow characters * * This class is also known as nsAFlat[C]String, where "flat" is used * to denote a null-terminated string. */ class nsTString_CharT : public nsTSubstring_CharT { public: typedef nsTString_CharT self_type; public: /** * constructors */ nsTString_CharT() : substring_type() {} explicit nsTString_CharT( const char_type* data, size_type length = size_type(-1) ) : substring_type() { Assign(data, length); } nsTString_CharT( const self_type& str ) : substring_type() { Assign(str); } nsTString_CharT( const substring_tuple_type& tuple ) : substring_type() { Assign(tuple); } explicit nsTString_CharT( const substring_type& readable ) : substring_type() { Assign(readable); } // |operator=| does not inherit, so we must define our own self_type& operator=( char_type c ) { Assign(c); return *this; } self_type& operator=( const char_type* data ) { Assign(data); return *this; } self_type& operator=( const self_type& str ) { Assign(str); return *this; } self_type& operator=( const substring_type& str ) { Assign(str); return *this; } self_type& operator=( const substring_tuple_type& tuple ) { Assign(tuple); return *this; } /** * returns the null-terminated string */ const char_type* get() const { return mData; } /** * returns character at specified index. * * NOTE: unlike nsTSubstring::CharAt, this function allows you to index * the null terminator character. */ char_type CharAt( index_type i ) const { NS_ASSERTION(i <= mLength, "index exceeds allowable range"); return mData[i]; } char_type operator[]( index_type i ) const { return CharAt(i); } #if MOZ_STRING_WITH_OBSOLETE_API /** * Search for the given substring within this string. * * @param aString is substring to be sought in this * @param aIgnoreCase selects case sensitivity * @param aOffset tells us where in this string to start searching * @param aCount tells us how far from the offset we are to search. Use * -1 to search the whole string. * @return offset in string, or kNotFound */ int32_t Find( const nsCString& aString, bool aIgnoreCase=false, int32_t aOffset=0, int32_t aCount=-1 ) const; int32_t Find( const char* aString, bool aIgnoreCase=false, int32_t aOffset=0, int32_t aCount=-1 ) const; #ifdef CharT_is_PRUnichar int32_t Find( const nsAFlatString& aString, int32_t aOffset=0, int32_t aCount=-1 ) const; int32_t Find( const PRUnichar* aString, int32_t aOffset=0, int32_t aCount=-1 ) const; #endif /** * This methods scans the string backwards, looking for the given string * * @param aString is substring to be sought in this * @param aIgnoreCase tells us whether or not to do caseless compare * @param aOffset tells us where in this string to start searching. * Use -1 to search from the end of the string. * @param aCount tells us how many iterations to make starting at the * given offset. * @return offset in string, or kNotFound */ int32_t RFind( const nsCString& aString, bool aIgnoreCase=false, int32_t aOffset=-1, int32_t aCount=-1 ) const; int32_t RFind( const char* aCString, bool aIgnoreCase=false, int32_t aOffset=-1, int32_t aCount=-1 ) const; #ifdef CharT_is_PRUnichar int32_t RFind( const nsAFlatString& aString, int32_t aOffset=-1, int32_t aCount=-1 ) const; int32_t RFind( const PRUnichar* aString, int32_t aOffset=-1, int32_t aCount=-1 ) const; #endif /** * Search for given char within this string * * @param aChar is the character to search for * @param aOffset tells us where in this string to start searching * @param aCount tells us how far from the offset we are to search. * Use -1 to search the whole string. * @return offset in string, or kNotFound */ // int32_t FindChar( PRUnichar aChar, int32_t aOffset=0, int32_t aCount=-1 ) const; int32_t RFindChar( PRUnichar aChar, int32_t aOffset=-1, int32_t aCount=-1 ) const; /** * This method searches this string for the first character found in * the given string. * * @param aString contains set of chars to be found * @param aOffset tells us where in this string to start searching * (counting from left) * @return offset in string, or kNotFound */ int32_t FindCharInSet( const char* aString, int32_t aOffset=0 ) const; int32_t FindCharInSet( const self_type& aString, int32_t aOffset=0 ) const { return FindCharInSet(aString.get(), aOffset); } #ifdef CharT_is_PRUnichar int32_t FindCharInSet( const PRUnichar* aString, int32_t aOffset=0 ) const; #endif /** * This method searches this string for the last character found in * the given string. * * @param aString contains set of chars to be found * @param aOffset tells us where in this string to start searching * (counting from left) * @return offset in string, or kNotFound */ int32_t RFindCharInSet( const char_type* aString, int32_t aOffset=-1 ) const; int32_t RFindCharInSet( const self_type& aString, int32_t aOffset=-1 ) const { return RFindCharInSet(aString.get(), aOffset); } /** * Compares a given string to this string. * * @param aString is the string to be compared * @param aIgnoreCase tells us how to treat case * @param aCount tells us how many chars to compare * @return -1,0,1 */ #ifdef CharT_is_char int32_t Compare( const char* aString, bool aIgnoreCase=false, int32_t aCount=-1 ) const; #endif /** * Equality check between given string and this string. * * @param aString is the string to check * @param aIgnoreCase tells us how to treat case * @param aCount tells us how many chars to compare * @return boolean */ #ifdef CharT_is_char bool EqualsIgnoreCase( const char* aString, int32_t aCount=-1 ) const { return Compare(aString, true, aCount) == 0; } #else bool EqualsIgnoreCase( const char* aString, int32_t aCount=-1 ) const; #endif // !CharT_is_PRUnichar /** * Perform string to double-precision float conversion. * * @param aErrorCode will contain error if one occurs * @return double-precision float rep of string value */ double ToDouble( nsresult* aErrorCode ) const; /** * Perform string to single-precision float conversion. * * @param aErrorCode will contain error if one occurs * @return single-precision float rep of string value */ float ToFloat( nsresult* aErrorCode ) const { return (float)ToDouble(aErrorCode); } /** * Perform string to int conversion. * @param aErrorCode will contain error if one occurs * @param aRadix tells us which radix to assume; kAutoDetect tells us to determine the radix for you. * @return int rep of string value, and possible (out) error code */ int32_t ToInteger( nsresult* aErrorCode, uint32_t aRadix=kRadix10 ) const; /** * Perform string to 64-bit int conversion. * @param aErrorCode will contain error if one occurs * @param aRadix tells us which radix to assume; kAutoDetect tells us to determine the radix for you. * @return 64-bit int rep of string value, and possible (out) error code */ int64_t ToInteger64( nsresult* aErrorCode, uint32_t aRadix=kRadix10 ) const; /** * |Left|, |Mid|, and |Right| are annoying signatures that seem better almost * any _other_ way than they are now. Consider these alternatives * * aWritable = aReadable.Left(17); // ...a member function that returns a |Substring| * aWritable = Left(aReadable, 17); // ...a global function that returns a |Substring| * Left(aReadable, 17, aWritable); // ...a global function that does the assignment * * as opposed to the current signature * * aReadable.Left(aWritable, 17); // ...a member function that does the assignment * * or maybe just stamping them out in favor of |Substring|, they are just duplicate functionality * * aWritable = Substring(aReadable, 0, 17); */ size_type Mid( self_type& aResult, uint32_t aStartPos, uint32_t aCount ) const; size_type Left( self_type& aResult, size_type aCount ) const { return Mid(aResult, 0, aCount); } size_type Right( self_type& aResult, size_type aCount ) const { aCount = XPCOM_MIN(mLength, aCount); return Mid(aResult, mLength - aCount, aCount); } /** * Set a char inside this string at given index * * @param aChar is the char you want to write into this string * @param anIndex is the ofs where you want to write the given char * @return TRUE if successful */ bool SetCharAt( PRUnichar aChar, uint32_t aIndex ); /** * These methods are used to remove all occurrences of the * characters found in aSet from this string. * * @param aSet -- characters to be cut from this */ void StripChars( const char* aSet ); /** * This method strips whitespace throughout the string. */ void StripWhitespace(); /** * swaps occurence of 1 string for another */ void ReplaceChar( char_type aOldChar, char_type aNewChar ); void ReplaceChar( const char* aSet, char_type aNewChar ); void ReplaceSubstring( const self_type& aTarget, const self_type& aNewValue); void ReplaceSubstring( const char_type* aTarget, const char_type* aNewValue); /** * This method trims characters found in aTrimSet from * either end of the underlying string. * * @param aSet -- contains chars to be trimmed from both ends * @param aEliminateLeading * @param aEliminateTrailing * @param aIgnoreQuotes -- if true, causes surrounding quotes to be ignored * @return this */ void Trim( const char* aSet, bool aEliminateLeading=true, bool aEliminateTrailing=true, bool aIgnoreQuotes=false ); /** * This method strips whitespace from string. * You can control whether whitespace is yanked from start and end of * string as well. * * @param aEliminateLeading controls stripping of leading ws * @param aEliminateTrailing controls stripping of trailing ws */ void CompressWhitespace( bool aEliminateLeading=true, bool aEliminateTrailing=true ); /** * assign/append/insert with _LOSSY_ conversion */ void AssignWithConversion( const nsTAString_IncompatibleCharT& aString ); void AssignWithConversion( const incompatible_char_type* aData, int32_t aLength=-1 ); #endif // !MOZ_STRING_WITH_OBSOLETE_API protected: explicit nsTString_CharT( uint32_t flags ) : substring_type(flags) {} // allow subclasses to initialize fields directly nsTString_CharT( char_type* data, size_type length, uint32_t flags ) : substring_type(data, length, flags) {} }; class nsTFixedString_CharT : public nsTString_CharT { public: typedef nsTFixedString_CharT self_type; typedef nsTFixedString_CharT fixed_string_type; public: /** * @param data * fixed-size buffer to be used by the string (the contents of * this buffer may be modified by the string) * @param storageSize * the size of the fixed buffer * @param length (optional) * the length of the string already contained in the buffer */ nsTFixedString_CharT( char_type* data, size_type storageSize ) : string_type(data, uint32_t(char_traits::length(data)), F_TERMINATED | F_FIXED | F_CLASS_FIXED) , mFixedCapacity(storageSize - 1) , mFixedBuf(data) {} nsTFixedString_CharT( char_type* data, size_type storageSize, size_type length ) : string_type(data, length, F_TERMINATED | F_FIXED | F_CLASS_FIXED) , mFixedCapacity(storageSize - 1) , mFixedBuf(data) { // null-terminate mFixedBuf[length] = char_type(0); } // |operator=| does not inherit, so we must define our own self_type& operator=( char_type c ) { Assign(c); return *this; } self_type& operator=( const char_type* data ) { Assign(data); return *this; } self_type& operator=( const substring_type& str ) { Assign(str); return *this; } self_type& operator=( const substring_tuple_type& tuple ) { Assign(tuple); return *this; } protected: friend class nsTSubstring_CharT; size_type mFixedCapacity; char_type *mFixedBuf; }; /** * nsTAutoString_CharT * * Subclass of nsTString_CharT that adds support for stack-based string * allocation. It is normally not a good idea to use this class on the * heap, because it will allocate space which may be wasted if the string * it contains is significantly smaller or any larger than 64 characters. * * NAMES: * nsAutoString for wide characters * nsAutoCString for narrow characters */ class NS_STACK_CLASS nsTAutoString_CharT : public nsTFixedString_CharT { public: typedef nsTAutoString_CharT self_type; public: /** * constructors */ nsTAutoString_CharT() : fixed_string_type(mStorage, kDefaultStorageSize, 0) {} explicit nsTAutoString_CharT( char_type c ) : fixed_string_type(mStorage, kDefaultStorageSize, 0) { Assign(c); } explicit nsTAutoString_CharT( const char_type* data, size_type length = size_type(-1) ) : fixed_string_type(mStorage, kDefaultStorageSize, 0) { Assign(data, length); } nsTAutoString_CharT( const self_type& str ) : fixed_string_type(mStorage, kDefaultStorageSize, 0) { Assign(str); } explicit nsTAutoString_CharT( const substring_type& str ) : fixed_string_type(mStorage, kDefaultStorageSize, 0) { Assign(str); } nsTAutoString_CharT( const substring_tuple_type& tuple ) : fixed_string_type(mStorage, kDefaultStorageSize, 0) { Assign(tuple); } // |operator=| does not inherit, so we must define our own self_type& operator=( char_type c ) { Assign(c); return *this; } self_type& operator=( const char_type* data ) { Assign(data); return *this; } self_type& operator=( const self_type& str ) { Assign(str); return *this; } self_type& operator=( const substring_type& str ) { Assign(str); return *this; } self_type& operator=( const substring_tuple_type& tuple ) { Assign(tuple); return *this; } enum { kDefaultStorageSize = 64 }; private: char_type mStorage[kDefaultStorageSize]; }; // // nsAutoString stores pointers into itself which are invalidated when an // nsTArray is resized, so nsTArray must not be instantiated with nsAutoString // elements! // template class nsTArrayElementTraits; template<> class nsTArrayElementTraits { public: template struct Dont_Instantiate_nsTArray_of; template struct Instead_Use_nsTArray_of; static Dont_Instantiate_nsTArray_of * Construct(Instead_Use_nsTArray_of *e) { return 0; } template static Dont_Instantiate_nsTArray_of * Construct(Instead_Use_nsTArray_of *e, const A &arg) { return 0; } static Dont_Instantiate_nsTArray_of * Destruct(Instead_Use_nsTArray_of *e) { return 0; } }; /** * nsTXPIDLString extends nsTString such that: * * (1) mData can be null * (2) objects of this type can be automatically cast to |const CharT*| * (3) getter_Copies method is supported to adopt data allocated with * NS_Alloc, such as "out string" parameters in XPIDL. * * NAMES: * nsXPIDLString for wide characters * nsXPIDLCString for narrow characters */ class nsTXPIDLString_CharT : public nsTString_CharT { public: typedef nsTXPIDLString_CharT self_type; public: nsTXPIDLString_CharT() : string_type(char_traits::sEmptyBuffer, 0, F_TERMINATED | F_VOIDED) {} // copy-constructor required to avoid default nsTXPIDLString_CharT( const self_type& str ) : string_type(char_traits::sEmptyBuffer, 0, F_TERMINATED | F_VOIDED) { Assign(str); } // return nullptr if we are voided const char_type* get() const { return (mFlags & F_VOIDED) ? nullptr : mData; } // this case operator is the reason why this class cannot just be a // typedef for nsTString operator const char_type*() const { return get(); } // need this to diambiguous operator[int] char_type operator[]( int32_t i ) const { return CharAt(index_type(i)); } // |operator=| does not inherit, so we must define our own self_type& operator=( char_type c ) { Assign(c); return *this; } self_type& operator=( const char_type* data ) { Assign(data); return *this; } self_type& operator=( const self_type& str ) { Assign(str); return *this; } self_type& operator=( const substring_type& str ) { Assign(str); return *this; } self_type& operator=( const substring_tuple_type& tuple ) { Assign(tuple); return *this; } }; /** * getter_Copies support for use with raw string out params: * * NS_IMETHOD GetBlah(char**); * * void some_function() * { * nsXPIDLCString blah; * GetBlah(getter_Copies(blah)); * // ... * } */ class NS_STACK_CLASS nsTGetterCopies_CharT { public: typedef CharT char_type; nsTGetterCopies_CharT(nsTSubstring_CharT& str) : mString(str), mData(nullptr) {} ~nsTGetterCopies_CharT() { mString.Adopt(mData); // OK if mData is null } operator char_type**() { return &mData; } private: nsTSubstring_CharT& mString; char_type* mData; }; inline nsTGetterCopies_CharT getter_Copies( nsTSubstring_CharT& aString ) { return nsTGetterCopies_CharT(aString); } /** * nsTAdoptingString extends nsTXPIDLString such that: * * (1) Adopt given string on construction or assignment, i.e. take * the value of what's given, and make what's given forget its * value. Note that this class violates constness in a few * places. Be careful! */ class nsTAdoptingString_CharT : public nsTXPIDLString_CharT { public: typedef nsTAdoptingString_CharT self_type; public: explicit nsTAdoptingString_CharT() {} explicit nsTAdoptingString_CharT(char_type* str, size_type length = size_type(-1)) { Adopt(str, length); } // copy-constructor required to adopt on copy. Note that this // will violate the constness of |str| in the operator=() // call. |str| will be truncated as a side-effect of this // constructor. nsTAdoptingString_CharT( const self_type& str ) { *this = str; } // |operator=| does not inherit, so we must define our own self_type& operator=( const substring_type& str ) { Assign(str); return *this; } self_type& operator=( const substring_tuple_type& tuple ) { Assign(tuple); return *this; } // Adopt(), if possible, when assigning to a self_type&. Note // that this violates the constness of str, str is always // truncated when this operator is called. self_type& operator=( const self_type& str ); private: self_type& operator=( const char_type* data ) MOZ_DELETE; self_type& operator=( char_type* data ) MOZ_DELETE; };