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671 lines
25 KiB
671 lines
25 KiB
/*==LICENSE==* |
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CyanWorlds.com Engine - MMOG client, server and tools |
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Copyright (C) 2011 Cyan Worlds, Inc. |
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This program is free software: you can redistribute it and/or modify |
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it under the terms of the GNU General Public License as published by |
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the Free Software Foundation, either version 3 of the License, or |
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(at your option) any later version. |
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This program is distributed in the hope that it will be useful, |
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but WITHOUT ANY WARRANTY; without even the implied warranty of |
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the |
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GNU General Public License for more details. |
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You should have received a copy of the GNU General Public License |
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along with this program. If not, see <http://www.gnu.org/licenses/>. |
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Additional permissions under GNU GPL version 3 section 7 |
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If you modify this Program, or any covered work, by linking or |
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combining it with any of RAD Game Tools Bink SDK, Autodesk 3ds Max SDK, |
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NVIDIA PhysX SDK, Microsoft DirectX SDK, OpenSSL library, Independent |
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JPEG Group JPEG library, Microsoft Windows Media SDK, or Apple QuickTime SDK |
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(or a modified version of those libraries), |
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containing parts covered by the terms of the Bink SDK EULA, 3ds Max EULA, |
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PhysX SDK EULA, DirectX SDK EULA, OpenSSL and SSLeay licenses, IJG |
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JPEG Library README, Windows Media SDK EULA, or QuickTime SDK EULA, the |
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licensors of this Program grant you additional |
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permission to convey the resulting work. Corresponding Source for a |
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non-source form of such a combination shall include the source code for |
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the parts of OpenSSL and IJG JPEG Library used as well as that of the covered |
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work. |
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You can contact Cyan Worlds, Inc. by email legal@cyan.com |
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or by snail mail at: |
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Cyan Worlds, Inc. |
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14617 N Newport Hwy |
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Mead, WA 99021 |
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*==LICENSE==*/ |
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#ifndef plString_Defined |
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#define plString_Defined |
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#include <stdint.h> |
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#include <vector> |
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/** Single Unicode character code unit */ |
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typedef unsigned int UniChar; |
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#define SSO_CHARS (16) |
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#define STRING_STACK_SIZE (256) |
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#define WHITESPACE_CHARS " \t\n\r" |
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|
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/** Ref-counted string data buffer. |
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* This is used to store actual string data in any (unchecked) encoding format, |
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* including both the internal UTF-8 data of plString itself as well as the |
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* temporaries returned in the conversion operators. |
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* \sa plString |
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*/ |
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template <typename _Ch> |
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class plStringBuffer |
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{ |
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private: |
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struct StringRef |
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{ |
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unsigned int fRefs; |
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const _Ch *fStringData; |
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StringRef(const _Ch *data) |
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: fRefs(1), fStringData(data) { } |
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|
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inline void AddRef() { ++fRefs; } |
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inline void DecRef() |
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{ |
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if (--fRefs == 0) { |
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delete [] fStringData; |
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delete this; |
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} |
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} |
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}; |
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union { |
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StringRef *fData; |
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_Ch fShort[SSO_CHARS]; |
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}; |
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size_t fSize; |
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bool IHaveACow() const { return fSize >= SSO_CHARS; } |
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public: |
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/** Construct an empty string buffer. */ |
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plStringBuffer() : fSize(0) { memset(fShort, 0, sizeof(fShort)); } |
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/** Copy constructor - adds a reference to the copied buffer */ |
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plStringBuffer(const plStringBuffer<_Ch> ©) : fSize(copy.fSize) |
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{ |
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memcpy(fShort, copy.fShort, sizeof(fShort)); |
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if (IHaveACow()) |
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fData->AddRef(); |
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} |
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/** Construct a string buffer which holds a COPY of the \a data, up to |
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* \a size characters. The terminating '\0' is added automatically, |
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* meaning this constructor is safe to use on buffers which are not |
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* already null-terminated. |
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*/ |
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plStringBuffer(const _Ch *data, size_t size) : fSize(size) |
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{ |
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memset(fShort, 0, sizeof(fShort)); |
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_Ch *copyData = IHaveACow() ? new _Ch[size + 1] : fShort; |
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memcpy(copyData, data, size); |
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copyData[size] = 0; |
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if (IHaveACow()) |
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fData = new StringRef(copyData); |
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} |
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/** Destructor. The ref-counted data will only be freed if no other |
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* string buffers still reference it. |
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*/ |
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~plStringBuffer<_Ch>() |
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{ |
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if (IHaveACow()) |
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fData->DecRef(); |
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} |
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/** Assignment operator. Changes the reference to point to the |
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* copied buffer in \a copy. |
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*/ |
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plStringBuffer<_Ch> &operator=(const plStringBuffer<_Ch> ©) |
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{ |
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if (copy.IHaveACow()) |
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copy.fData->AddRef(); |
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if (IHaveACow()) |
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fData->DecRef(); |
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memcpy(fShort, copy.fShort, sizeof(fShort)); |
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fSize = copy.fSize; |
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return *this; |
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} |
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/** Returns a pointer to the referenced string buffer. */ |
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const _Ch *GetData() const { return IHaveACow() ? fData->fStringData : fShort; } |
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/** Returns the number of characters (not including the '\0') in the |
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* referenced string buffer. |
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*/ |
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size_t GetSize() const { return fSize; } |
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|
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/** Cast operator. This is a shortcut for not needing to call GetData on |
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* buffer objects passed to methods or objects expecting a C-style string. |
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*/ |
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operator const _Ch *() const { return GetData(); } |
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/** Create a writable buffer for \a size characters. |
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* From Haxxia with love! This will release the current string buffer |
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* reference and then create a new buffer with space for \a size |
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* characters, plus one extra for the terminating '\0'. The newly |
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* allocated buffer is returned as a non-const pointer, so it can be |
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* written to without having to use a \c const_cast. |
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* \warning The caller is expected to null-terminate the returned buffer. |
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* Not doing so may cause problems for functions and objects |
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* expecting a null-terminated C-style string. |
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*/ |
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_Ch *CreateWritableBuffer(size_t size) |
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{ |
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if (IHaveACow()) |
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fData->DecRef(); |
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fSize = size; |
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if (IHaveACow()) { |
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_Ch *writable = new _Ch[fSize + 1]; |
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fData = new StringRef(writable); |
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return writable; |
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} else { |
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return fShort; |
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} |
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} |
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}; |
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/** A plStringBuffer for storing fully-expanded Unicode data */ |
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typedef plStringBuffer<UniChar> plUnicodeBuffer; |
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/** Unicode-capable and (mostly) binary safe string class. |
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* plString stores SSO-optimized or reference counted strings (automatically |
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* determined based on string length) for easy and performant string data |
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* storage and manipulation. The internal format of plString is UTF-8, |
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* meaning it keeps all Unicode information from conversions. plStrings |
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* are safe to share without making explicit copies, since plStrings |
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* follow the strings-are-immutable philosophy. Anything which mutates |
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* a plString object will do so in a new string buffer, allowing other |
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* string objects to retain the old data without getting unexpected changes. |
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*/ |
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class plString |
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{ |
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public: |
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enum { |
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/** Automatically determine the size of input (Requires input to be |
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* correctly null-terminated). |
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*/ |
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kSizeAuto = (size_t)(0x80000000) |
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}; |
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/** Represents a "null" plString object. */ |
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static const plString Null; |
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private: |
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plStringBuffer<char> fUtf8Buffer; |
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void IConvertFromUtf8(const char *utf8, size_t size); |
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void IConvertFromUtf16(const uint16_t *utf16, size_t size); |
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void IConvertFromWchar(const wchar_t *wstr, size_t size); |
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void IConvertFromUtf32(const UniChar *ustr, size_t size); |
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void IConvertFromIso8859_1(const char *astr, size_t size); |
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public: |
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/** Construct a valid, empty string. */ |
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plString() { } |
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/** Construct a string from a C-style string. |
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* \note This constructor expects the input to be UTF-8 encoded. For |
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* conversion from ISO-8859-1 8-bit data, use FromIso8859_1(). |
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*/ |
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plString(const char *cstr, size_t size = kSizeAuto) { IConvertFromUtf8(cstr, size); } |
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/** Copy constructor. */ |
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plString(const plString ©) : fUtf8Buffer(copy.fUtf8Buffer) { } |
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/** Copy constructor from plStringBuffer<char>. |
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* \note This constructor expects the input to be UTF-8 encoded. For |
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* conversion from ISO-8859-1 8-bit data, use FromIso8859_1(). |
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*/ |
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plString(const plStringBuffer<char> &init) { operator=(init); } |
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/** Construct a string from expanded Unicode data. */ |
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plString(const plUnicodeBuffer &init) { IConvertFromUtf32(init.GetData(), init.GetSize()); } |
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/** Assignment operator. Same as plString(const char *). */ |
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plString &operator=(const char *cstr) { IConvertFromUtf8(cstr, kSizeAuto); return *this; } |
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/** Assignment operator. Same as plString(const plString &). */ |
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plString &operator=(const plString ©) { fUtf8Buffer = copy.fUtf8Buffer; return *this; } |
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/** Assignment operator. Same as plString(const plStringBuffer<char> &). */ |
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plString &operator=(const plStringBuffer<char> &init); |
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/** Assignment operator. Same as plString(const plUnicodeBuffer &). */ |
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plString &operator=(const plUnicodeBuffer &init) { IConvertFromUtf32(init.GetData(), init.GetSize()); return *this; } |
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/** Append UTF-8 data from a C-style string pointer to the end of this |
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* string object. |
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* \sa plStringStream |
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*/ |
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plString &operator+=(const char *cstr) { return operator=(*this + cstr); } |
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/** Append the string \a str to the end of this string object. |
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* \sa plStringStream |
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*/ |
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plString &operator+=(const plString &str) { return operator=(*this + str); } |
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/** Create a new plString object from the UTF-8 formatted data in \a utf8. */ |
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static inline plString FromUtf8(const char *utf8, size_t size = kSizeAuto) |
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{ |
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plString str; |
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str.IConvertFromUtf8(utf8, size); |
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return str; |
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} |
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/** Create a new plString object from the UTF-16 formatted data in \a utf16. */ |
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static inline plString FromUtf16(const uint16_t *utf16, size_t size = kSizeAuto) |
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{ |
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plString str; |
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str.IConvertFromUtf16(utf16, size); |
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return str; |
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} |
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/** Create a new plString object from the \p wchar_t data in \a wstr. */ |
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static inline plString FromWchar(const wchar_t *wstr, size_t size = kSizeAuto) |
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{ |
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plString str; |
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str.IConvertFromWchar(wstr, size); |
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return str; |
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} |
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/** Create a new plString object from the UTF-32 formatted data in \a utf32. */ |
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static inline plString FromUtf32(const UniChar *utf32, size_t size = kSizeAuto) |
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{ |
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plString str; |
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str.IConvertFromUtf32(utf32, size); |
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return str; |
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} |
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/** Create a new plString object from the ISO-8859-1 formatted data in \a astr. */ |
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static inline plString FromIso8859_1(const char *astr, size_t size = kSizeAuto) |
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{ |
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plString str; |
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str.IConvertFromIso8859_1(astr, size); |
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return str; |
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} |
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/** Return the internal UTF-8 data pointer for use in functions and objects |
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* expecting C-style string pointers. If this string is empty, returns |
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* \a substitute instead. |
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*/ |
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const char *c_str(const char *substitute = "") const |
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{ return IsEmpty() ? substitute : fUtf8Buffer.GetData(); } |
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/** Return the byte at position \a position. Note that this may be in |
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* the middle of a UTF-8 sequence -- if you want an actual Unicode |
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* character, use the buffer returned from GetUnicodeArray() instead. |
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*/ |
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char CharAt(size_t position) const { return c_str()[position]; } |
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/** Returns the internal UTF-8 data buffer object. */ |
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plStringBuffer<char> ToUtf8() const { return fUtf8Buffer; } |
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/** Convert this string's data to a UTF-16 string buffer. */ |
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plStringBuffer<uint16_t> ToUtf16() const; |
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/** Convert this string's data to a wchar_t string buffer. |
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* \note Depending on your platform and compiler configuration, this |
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* will either return UTF-16 or UTF-32 data -- it will never |
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* return a non-unicode data buffer. |
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*/ |
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plStringBuffer<wchar_t> ToWchar() const; |
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/** Convert this string's data as closely as possible to ISO-8859-1. |
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* Unicode characters outside of the ISO-8859-1 range will be stored |
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* in the buffer as a question mark ('?'). |
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*/ |
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plStringBuffer<char> ToIso8859_1() const; |
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/** Convert the string's data to a fully expanded UTF-32 buffer. This |
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* makes it easy to operate on actual Unicode characters instead of |
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* UTF-8 bytes (e.g. for use in rendering characters to a display). |
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*/ |
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plUnicodeBuffer GetUnicodeArray() const; |
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/** Returns the size in number of bytes (excluding the null-terminator) of |
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* this string. |
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*/ |
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size_t GetSize() const { return fUtf8Buffer.GetSize(); } |
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/** Returns \c true if this string is empty (""). */ |
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bool IsEmpty() const { return fUtf8Buffer.GetSize() == 0; } |
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/** Returns \c true if this string is "null". Currently, this is just |
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* a synonym for IsEmpty(), as plString makes no distinction between |
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* null and empty strings. |
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* \todo Evaluate whether Plasma actually needs to distinguish between |
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* empty and NULL strings. Ideally, only IsEmpty should be required. |
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*/ |
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bool IsNull() const { return IsEmpty(); } |
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/** Convert the string data to an integer in base \a base. |
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* If base is set to 0, this function behaves like strtol, which checks |
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* for hex or octal prefixes (e.g. 0777 or 0x1234), and assumes base 10 |
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* if none are found. |
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*/ |
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int ToInt(int base = 0) const; |
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/** Convert the string to an unsigned integer in base \a base. |
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* If base is set to 0, this function behaves like strtoul, which checks |
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* for hex or octal prefixes (e.g. 0777 or 0x1234), and assumes base 10 |
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* if none are found. |
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*/ |
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unsigned int ToUInt(int base = 0) const; |
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/** Convert the string to a floating point value. */ |
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float ToFloat() const; |
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/** Convert the string to a double precision floating point value. */ |
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double ToDouble() const; |
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/** Construct a plString using a printf-like format string. */ |
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static plString Format(const char *fmt, ...); |
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/** Construct a plString using a printf-like format string. |
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* This function should be called inside of vararg functions, such as |
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* plString::Format(). |
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*/ |
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static plString IFormat(const char *fmt, va_list vptr); |
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enum CaseSensitivity { |
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kCaseSensitive, kCaseInsensitive |
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}; |
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/** Compare this string with \a str. |
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* \return an integer which indicates: |
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* \li \p =0 - the strings are equal |
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* \li \p \<0 - this string is lexicographically less than \a str |
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* \li \p \>0 - this string is lexicographically greater than \a str |
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*/ |
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int Compare(const plString &str, CaseSensitivity sense = kCaseSensitive) const |
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{ |
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return (sense == kCaseSensitive) ? strcmp(c_str(), str.c_str()) |
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: stricmp(c_str(), str.c_str()); |
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} |
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/** Compare this string with \a str. |
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* \return an integer which indicates: |
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* \li \p =0 - the strings are equal |
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* \li \p \<0 - this string is lexicographically less than \a str |
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* \li \p \>0 - this string is lexicographically greater than \a str |
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*/ |
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int Compare(const char *str, CaseSensitivity sense = kCaseSensitive) const |
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{ |
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return (sense == kCaseSensitive) ? strcmp(c_str(), str ? str : "") |
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: stricmp(c_str(), str ? str : ""); |
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} |
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/** Compare up to but never exceeding the first \a count bytes of this |
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* string with \a str. |
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* \sa Compare(const plString &, CaseSensitivity) const |
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*/ |
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int CompareN(const plString &str, size_t count, CaseSensitivity sense = kCaseSensitive) const |
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{ |
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return (sense == kCaseSensitive) ? strncmp(c_str(), str.c_str(), count) |
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: strnicmp(c_str(), str.c_str(), count); |
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} |
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/** Compare up to but never exceeding the first \a count bytes of this |
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* string with \a str. |
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* \sa Compare(const char *, CaseSensitivity) const |
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*/ |
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int CompareN(const char *str, size_t count, CaseSensitivity sense = kCaseSensitive) const |
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{ |
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return (sense == kCaseSensitive) ? strncmp(c_str(), str ? str : "", count) |
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: strnicmp(c_str(), str ? str : "", count); |
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} |
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/** Shortcut for Compare(str, kCaseInsensitive). */ |
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int CompareI(const plString &str) const { return Compare(str, kCaseInsensitive); } |
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/** Shortcut for Compare(str, kCaseInsensitive). */ |
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int CompareI(const char *str) const { return Compare(str, kCaseInsensitive); } |
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/** Shortcut for CompareN(str, kCaseInsensitive). */ |
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int CompareNI(const plString &str, size_t count) const { return CompareN(str, count, kCaseInsensitive); } |
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/** Shortcut for CompareN(str, kCaseInsensitive). */ |
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int CompareNI(const char *str, size_t count) const { return CompareN(str, count, kCaseInsensitive); } |
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/** Operator overload for use in containers which depend on \c std::less. */ |
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bool operator<(const plString &other) const { return Compare(other) < 0; } |
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/** Test if this string contains the same string data as \a other. */ |
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bool operator==(const char *other) const { return Compare(other) == 0; } |
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/** Test if this string contains the same string data as \a other. */ |
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bool operator==(const plString &other) const { return Compare(other) == 0; } |
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/** Inverse of operator==(const char *) const. */ |
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bool operator!=(const char *other) const { return Compare(other) != 0; } |
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/** Inverse of operator==(const plString &) const. */ |
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bool operator!=(const plString &other) const { return Compare(other) != 0; } |
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/** Find the index of the first instance of \a ch in this string. |
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* \return -1 if the character was not found. |
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*/ |
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int Find(char ch, CaseSensitivity sense = kCaseSensitive) const; |
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/** Find the index of the last instance of \a ch in this string. |
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* \return -1 if the character was not found. |
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*/ |
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int FindLast(char ch, CaseSensitivity sense = kCaseSensitive) const; |
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/** Find the index of the first instance of \a str in this string. |
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* \return -1 if the substring was not found. |
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*/ |
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int Find(const char *str, CaseSensitivity sense = kCaseSensitive) const; |
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/** Find the index of the first instance of \a str in this string. |
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* \return -1 if the substring was not found. |
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*/ |
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int Find(const plString &str, CaseSensitivity sense = kCaseSensitive) const |
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{ return Find(str.c_str(), sense); } |
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/** Check that this string matches the specified regular expression. |
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* This with only return true if the whole string can be matched |
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* by \a pattern. |
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*/ |
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bool REMatch(const char *pattern, CaseSensitivity sense = kCaseSensitive) const; |
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/** Search for substrings which match the specified regular expression. |
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* If capture groups are specified in the pattern, they will be |
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* returned as additional strings in the returned vector, starting at |
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* index 1 (index 0 contains the whole match). If the pattern was not |
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* found, this returns an empty vector. |
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*/ |
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std::vector<plString> RESearch(const char *pattern, CaseSensitivity sense = kCaseSensitive) const; |
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|
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/** Trim any characters in the supplied \a charset from the left of |
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* this string. |
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*/ |
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plString TrimLeft(const char *charset = WHITESPACE_CHARS) const; |
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/** Trim any characters in the supplied \a charset from the right of |
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* this string. |
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*/ |
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plString TrimRight(const char *charset = WHITESPACE_CHARS) const; |
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/** Trim any characters in the supplied \a charset from both ends of |
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* this string. Logically equivalent to (but more efficient than) |
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* str.TrimLeft(charset).TrimRight(charset) |
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*/ |
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plString Trim(const char *charset = WHITESPACE_CHARS) const; |
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|
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/** Return a substring starting at index \a start, with up to \a size |
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* characters from the start position. If \a size is greater than the |
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* number of characters left in the string after \a start, Substr will |
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* return the remainder of the string. |
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*/ |
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plString Substr(int start, size_t size = kSizeAuto) const; |
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|
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/** Return a substring containing at most \a size characters from the left |
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* of the string. Equivalent to Substr(0, size). |
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*/ |
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plString Left(size_t size) const { return Substr(0, size); } |
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|
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/** Return a substring containing at most \a size characters from the right |
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* of the string. Equivalent to Substr(GetSize() - size, size). |
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*/ |
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plString Right(size_t size) const { return Substr(GetSize() - size, size); } |
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|
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/** Return a copy of this string with all occurances of \a from replaced |
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* with \a to. */ |
|
plString Replace(const char *from, const char *to) const; |
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|
|
/** Return a copy of this string with all Latin-1 alphabetic characters |
|
* converted to upper case. |
|
* \sa CompareI() |
|
*/ |
|
plString ToUpper() const; |
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|
|
/** Return a copy of this string with all Latin-1 alphabetic characters |
|
* converted to lower case. |
|
* \sa CompareI() |
|
*/ |
|
plString ToLower() const; |
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|
|
/** Split this string into pieces separated by the substring \a split. |
|
* This will return the complete contents of everything between split |
|
* markers, meaning that two subsequent markers will produce an empty |
|
* string in the returned vector. |
|
* \sa Tokenize() |
|
*/ |
|
std::vector<plString> Split(const char *split, size_t maxSplits = kSizeAuto) const; |
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|
|
/** Split this string into tokens, delimited by \a delims. |
|
* Note that, unlike Split(), Tokenize will return only non-blank strings |
|
* after stripping out all delimiters between tokens. |
|
* \sa Split() |
|
*/ |
|
std::vector<plString> Tokenize(const char *delims = WHITESPACE_CHARS) const; |
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|
|
/** Create a string initialized with \a count copies of the character \a c. */ |
|
static plString Fill(size_t count, char c); |
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|
|
public: |
|
/** Functor which compares two strings case-insensitively for sorting. */ |
|
struct less_i |
|
{ |
|
bool operator()(const plString &_L, const plString &_R) const |
|
{ return _L.Compare(_R, kCaseInsensitive) < 0; } |
|
}; |
|
|
|
/** Functor which compares two strings case-insensitively for equality. */ |
|
struct equal_i |
|
{ |
|
bool operator()(const plString &_L, const plString &_R) const |
|
{ return _L.Compare(_R, kCaseInsensitive) == 0; } |
|
}; |
|
|
|
private: |
|
friend plString operator+(const plString &left, const plString &right); |
|
friend plString operator+(const plString &left, const char *right); |
|
friend plString operator+(const char *left, const plString &right); |
|
}; |
|
|
|
/** Concatenation operator for plStrings. */ |
|
plString operator+(const plString &left, const plString &right); |
|
|
|
/** Concatenation operator for plStrings and UTF-8 C-style string data. */ |
|
plString operator+(const plString &left, const char *right); |
|
|
|
/** Concatenation operator for plStrings and UTF-8 C-style string data. */ |
|
plString operator+(const char *left, const plString &right); |
|
|
|
|
|
/** Helper class for writing frequent data to a text buffer efficiently. |
|
* This should be used instead of plString::operator+=() for constructing |
|
* string data in pieces, as it keeps a running buffer instead of allocating |
|
* new storage for each append result. |
|
*/ |
|
class plStringStream |
|
{ |
|
public: |
|
/** Construct a new empty string stream. The first STRING_STACK_SIZE |
|
* bytes are allocated on the stack for further efficiency. |
|
*/ |
|
plStringStream() : fBufSize(STRING_STACK_SIZE), fLength(0) { } |
|
|
|
/** Destructor, frees any allocated heap memory owned by the stream. */ |
|
~plStringStream() { if (ICanHasHeap()) delete [] fBuffer; } |
|
|
|
/** Append string data to the end of the stream. */ |
|
plStringStream &append(const char *data, size_t length); |
|
|
|
/** Append UTF-8 C-style string data to the stream. */ |
|
plStringStream &operator<<(const char *text); |
|
|
|
/** Append a base-10 formatted signed integer to the stream. */ |
|
plStringStream &operator<<(int num); |
|
|
|
/** Append a base-10 formatted unsigned integer to the stream. */ |
|
plStringStream &operator<<(unsigned int num); |
|
|
|
/** Append a base-10 formatted float to the stream. */ |
|
plStringStream &operator<<(float num) { return operator<<(static_cast<double>(num)); } |
|
|
|
/** Append a base-10 formatted double to the stream. */ |
|
plStringStream &operator<<(double num); |
|
|
|
/** Append a single Latin-1 character to the stream. */ |
|
plStringStream &operator<<(char ch) { return append(&ch, 1); } |
|
|
|
/** Append the contents of \a text to the stream. */ |
|
plStringStream &operator<<(const plString &text) |
|
{ |
|
return append(text.c_str(), text.GetSize()); |
|
} |
|
|
|
/** Returns a pointer to the beginning of the stream buffer. |
|
* \warning This pointer is not null-terminated. |
|
*/ |
|
const char *GetRawBuffer() const |
|
{ |
|
return ICanHasHeap() ? fBuffer : fShort; |
|
} |
|
|
|
/** Return the size (in bytes) of the stream's data. */ |
|
size_t GetLength() const { return fLength; } |
|
|
|
/** Convert the stream's data to a UTF-8 string. */ |
|
plString GetString() const { return plString::FromUtf8(GetRawBuffer(), fLength); } |
|
|
|
/** Reset the stream's append pointer back to the beginning. |
|
* This does not incur a reallocation of the buffer -- it is left |
|
* with as much space as it had before, making this method more |
|
* useful for re-using string streams in loops. |
|
*/ |
|
void Truncate() { fLength = 0; } |
|
|
|
private: |
|
union { |
|
char *fBuffer; |
|
char fShort[STRING_STACK_SIZE]; |
|
}; |
|
size_t fBufSize, fLength; |
|
|
|
bool ICanHasHeap() const { return fBufSize > STRING_STACK_SIZE; } |
|
}; |
|
|
|
/** \p strlen implementation for UniChar based C-style string buffers. */ |
|
size_t ustrlen(const UniChar *ustr, size_t max = plString::kSizeAuto); |
|
|
|
#endif //plString_Defined
|
|
|