//========= Copyright Valve Corporation, All rights reserved. ============// // // Purpose: // // $NoKeywords: $ // // Serialization/unserialization buffer //=============================================================================// #ifndef UTLBUFFER_H #define UTLBUFFER_H #if _WIN32 && !defined(__GNUG__) #pragma once #endif #include #include "byteswap.h" #include "utlmemory.h" //----------------------------------------------------------------------------- // Forward declarations //----------------------------------------------------------------------------- struct characterset_t; //----------------------------------------------------------------------------- // Description of character conversions for string output // Here's an example of how to use the macros to define a character conversion // BEGIN_CHAR_CONVERSION( CStringConversion, '\\' ) // { '\n', "n" }, // { '\t', "t" } // END_CHAR_CONVERSION( CStringConversion, '\\' ) //----------------------------------------------------------------------------- class CUtlCharConversion { public: struct ConversionArray_t { char m_nActualChar; const char *m_pReplacementString; }; CUtlCharConversion(char nEscapeChar, const char *pDelimiter, int nCount, ConversionArray_t *pArray); char GetEscapeChar() const; const char *GetDelimiter() const; int GetDelimiterLength() const; const char *GetConversionString(char c) const; int GetConversionLength(char c) const; int MaxConversionLength() const; // Finds a conversion for the passed-in string, returns length virtual char FindConversion(const char *pString, int *pLength); protected: struct ConversionInfo_t { int m_nLength; const char *m_pReplacementString; }; char m_nEscapeChar; const char *m_pDelimiter; int m_nDelimiterLength; int m_nCount; int m_nMaxConversionLength; char m_pList[256]; ConversionInfo_t m_pReplacements[256]; }; #define BEGIN_CHAR_CONVERSION(_name, _delimiter, _escapeChar) \ static CUtlCharConversion::ConversionArray_t s_pConversionArray##_name[] = { #define END_CHAR_CONVERSION(_name, _delimiter, _escapeChar) \ } \ ; \ CUtlCharConversion _name( \ _escapeChar, _delimiter, \ sizeof(s_pConversionArray##_name) / \ sizeof(CUtlCharConversion::ConversionArray_t), \ s_pConversionArray##_name); #define BEGIN_CUSTOM_CHAR_CONVERSION(_className, _name, _delimiter, \ _escapeChar) \ static CUtlCharConversion::ConversionArray_t s_pConversionArray##_name[] = { #define END_CUSTOM_CHAR_CONVERSION(_className, _name, _delimiter, _escapeChar) \ } \ ; \ _className _name(_escapeChar, _delimiter, \ sizeof(s_pConversionArray##_name) / \ sizeof(CUtlCharConversion::ConversionArray_t), \ s_pConversionArray##_name); //----------------------------------------------------------------------------- // Character conversions for C strings //----------------------------------------------------------------------------- CUtlCharConversion *GetCStringCharConversion(); //----------------------------------------------------------------------------- // Character conversions for quoted strings, with no escape sequences //----------------------------------------------------------------------------- CUtlCharConversion *GetNoEscCharConversion(); //----------------------------------------------------------------------------- // Macro to set overflow functions easily //----------------------------------------------------------------------------- #define SetUtlBufferOverflowFuncs(_get, _put) \ SetOverflowFuncs(static_cast(_get), \ static_cast(_put)) //----------------------------------------------------------------------------- // Command parsing.. //----------------------------------------------------------------------------- class CUtlBuffer { public: enum SeekType_t { SEEK_HEAD = 0, SEEK_CURRENT, SEEK_TAIL }; // flags enum BufferFlags_t { TEXT_BUFFER = 0x1, // Describes how get + put work (as strings, or binary) EXTERNAL_GROWABLE = 0x2, // This is used w/ external buffers and causes // the utlbuf to switch to reallocatable // memory if an overflow happens when Putting. CONTAINS_CRLF = 0x4, // For text buffers only, does this contain \n or \n\r? READ_ONLY = 0x8, // For external buffers; prevents null termination // from happening. AUTO_TABS_DISABLED = 0x10, // Used to disable/enable push/pop tabs }; // Overflow functions when a get or put overflows typedef bool (CUtlBuffer::*UtlBufferOverflowFunc_t)(int nSize); // Constructors for growable + external buffers for // serialization/unserialization CUtlBuffer(int growSize = 0, int initSize = 0, int nFlags = 0); CUtlBuffer(const void *pBuffer, int size, int nFlags = 0); // This one isn't actually defined so that we catch contructors that are // trying to pass a bool in as the third param. CUtlBuffer(const void *pBuffer, int size, bool crap); unsigned char GetFlags() const; // NOTE: This will assert if you attempt to recast it in a way that // is not compatible. The only valid conversion is binary-> text w/CRLF void SetBufferType(bool bIsText, bool bContainsCRLF); // Makes sure we've got at least this much memory void EnsureCapacity(int num); // Attaches the buffer to external memory.... void SetExternalBuffer(void *pMemory, int nSize, int nInitialPut, int nFlags = 0); bool IsExternallyAllocated() const; // Takes ownership of the passed memory, including freeing it when this // buffer is destroyed. void AssumeMemory(void *pMemory, int nSize, int nInitialPut, int nFlags = 0); // copies data from another buffer void CopyBuffer(const CUtlBuffer &buffer); void CopyBuffer(const void *pubData, int cubData); void Swap(CUtlBuffer &buf); void Swap(CUtlMemory &mem); FORCEINLINE void ActivateByteSwappingIfBigEndian(void) { if (IsX360()) ActivateByteSwapping(true); } // Controls endian-ness of binary utlbufs - default matches the current // platform void ActivateByteSwapping(bool bActivate); void SetBigEndian(bool bigEndian); bool IsBigEndian(void); // Resets the buffer; but doesn't free memory void Clear(); // Clears out the buffer; frees memory void Purge(); // Read stuff out. // Binary mode: it'll just read the bits directly in, and characters will be // read for strings until a null character is reached. // Text mode: it'll parse the file, turning text #s into real numbers. // GetString will read a string until a space is reached char GetChar(); unsigned char GetUnsignedChar(); short GetShort(); unsigned short GetUnsignedShort(); int GetInt(); int64 GetInt64(); int GetIntHex(); unsigned int GetUnsignedInt(); float GetFloat(); double GetDouble(); template void GetString(char (&pString)[maxLenInChars]) { GetStringInternal(pString, maxLenInChars); } void GetStringManualCharCount(char *pString, size_t maxLenInChars) { GetStringInternal(pString, maxLenInChars); } void Get(void *pMem, int size); void GetLine(char *pLine, int nMaxChars = 0); // Used for getting objects that have a byteswap datadesc defined template void GetObjects(T *dest, int count = 1); // This will get at least 1 byte and up to nSize bytes. // It will return the number of bytes actually read. int GetUpTo(void *pMem, int nSize); // This version of GetString converts \" to \\ and " to \, etc. // It also reads a " at the beginning and end of the string void GetDelimitedString(CUtlCharConversion *pConv, char *pString, int nMaxChars = 0); char GetDelimitedChar(CUtlCharConversion *pConv); // This will return the # of characters of the string about to be read out // NOTE: The count will *include* the terminating 0!! // In binary mode, it's the number of characters until the next 0 // In text mode, it's the number of characters until the next space. int PeekStringLength(); // This version of PeekStringLength converts \" to \\ and " to \, etc. // It also reads a " at the beginning and end of the string // NOTE: The count will *include* the terminating 0!! // In binary mode, it's the number of characters until the next 0 // In text mode, it's the number of characters between "s (checking for \") // Specifying false for bActualSize will return the pre-translated number of // characters including the delimiters and the escape characters. So, \n // counts as 2 characters when bActualSize == false and only 1 character // when bActualSize == true int PeekDelimitedStringLength(CUtlCharConversion *pConv, bool bActualSize = true); // Just like scanf, but doesn't work in binary mode int Scanf(SCANF_FORMAT_STRING const char *pFmt, ...); int VaScanf(const char *pFmt, va_list list); // Eats white space, advances Get index void EatWhiteSpace(); // Eats C++ style comments bool EatCPPComment(); // (For text buffers only) // Parse a token from the buffer: // Grab all text that lies between a starting delimiter + ending delimiter // (skipping whitespace that leads + trails both delimiters). // If successful, the get index is advanced and the function returns true, // otherwise the index is not advanced and the function returns false. bool ParseToken(const char *pStartingDelim, const char *pEndingDelim, char *pString, int nMaxLen); // Advance the get index until after the particular string is found // Do not eat whitespace before starting. Return false if it failed // String test is case-insensitive. bool GetToken(const char *pToken); // Parses the next token, given a set of character breaks to stop at // Returns the length of the token parsed in bytes (-1 if none parsed) int ParseToken(characterset_t *pBreaks, char *pTokenBuf, int nMaxLen, bool bParseComments = true); // Write stuff in // Binary mode: it'll just write the bits directly in, and strings will be // written with a null terminating character // Text mode: it'll convert the numbers to text versions // PutString will not write a terminating character void PutChar(char c); void PutUnsignedChar(unsigned char uc); void PutUint64(uint64 ub); void PutInt16(int16 s16); void PutShort(short s); void PutUnsignedShort(unsigned short us); void PutInt(int i); void PutInt64(int64 i); void PutUnsignedInt(unsigned int u); void PutFloat(float f); void PutDouble(double d); void PutString(const char *pString); void Put(const void *pMem, int size); // Used for putting objects that have a byteswap datadesc defined template void PutObjects(T *src, int count = 1); // This version of PutString converts \ to \\ and " to \", etc. // It also places " at the beginning and end of the string void PutDelimitedString(CUtlCharConversion *pConv, const char *pString); void PutDelimitedChar(CUtlCharConversion *pConv, char c); // Just like printf, writes a terminating zero in binary mode void Printf(PRINTF_FORMAT_STRING const char *pFmt, ...) FMTFUNCTION(2, 3); void VaPrintf(const char *pFmt, va_list list); // What am I writing (put)/reading (get)? void *PeekPut(int offset = 0); const void *PeekGet(int offset = 0) const; const void *PeekGet(int nMaxSize, int nOffset); // Where am I writing (put)/reading (get)? int TellPut() const; int TellGet() const; // What's the most I've ever written? int TellMaxPut() const; // How many bytes remain to be read? // NOTE: This is not accurate for streaming text files; it overshoots int GetBytesRemaining() const; // Change where I'm writing (put)/reading (get) void SeekPut(SeekType_t type, int offset); void SeekGet(SeekType_t type, int offset); // Buffer base const void *Base() const; void *Base(); // Returns the base as a const char*, only valid in text mode. const char *String() const; // memory allocation size, does *not* reflect size written or read, // use TellPut or TellGet for that int Size() const; // Am I a text buffer? bool IsText() const; // Can I grow if I'm externally allocated? bool IsGrowable() const; // Am I valid? (overflow or underflow error), Once invalid it stays invalid bool IsValid() const; // Do I contain carriage return/linefeeds? bool ContainsCRLF() const; // Am I read-only bool IsReadOnly() const; // Converts a buffer from a CRLF buffer to a CR buffer (and back) // Returns false if no conversion was necessary (and outBuf is left // untouched) If the conversion occurs, outBuf will be cleared. bool ConvertCRLF(CUtlBuffer &outBuf); // Push/pop pretty-printing tabs void PushTab(); void PopTab(); // Temporarily disables pretty print void EnableTabs(bool bEnable); protected: // error flags enum { PUT_OVERFLOW = 0x1, GET_OVERFLOW = 0x2, MAX_ERROR_FLAG = GET_OVERFLOW, }; void SetOverflowFuncs(UtlBufferOverflowFunc_t getFunc, UtlBufferOverflowFunc_t putFunc); bool OnPutOverflow(int nSize); bool OnGetOverflow(int nSize); protected: // Checks if a get/put is ok bool CheckPut(int size); bool CheckGet(int size); void AddNullTermination(); // Methods to help with pretty-printing bool WasLastCharacterCR(); void PutTabs(); // Help with delimited stuff char GetDelimitedCharInternal(CUtlCharConversion *pConv); void PutDelimitedCharInternal(CUtlCharConversion *pConv, char c); // Default overflow funcs bool PutOverflow(int nSize); bool GetOverflow(int nSize); // Does the next bytes of the buffer match a pattern? bool PeekStringMatch(int nOffset, const char *pString, int nLen); // Peek size of line to come, check memory bound int PeekLineLength(); // How much whitespace should I skip? int PeekWhiteSpace(int nOffset); // Checks if a peek get is ok bool CheckPeekGet(int nOffset, int nSize); // Call this to peek arbitrarily long into memory. It doesn't fail unless // it can't read *anything* new bool CheckArbitraryPeekGet(int nOffset, int &nIncrement); void GetStringInternal(char *pString, size_t maxLenInChars); template void GetType(T &dest, const char *pszFmt); template void GetTypeBin(T &dest); template void GetObject(T *src); template void PutType(T src, const char *pszFmt); template void PutTypeBin(T src); template void PutObject(T *src); CUtlMemory m_Memory; int m_Get; int m_Put; unsigned char m_Error; unsigned char m_Flags; unsigned char m_Reserved; #if defined(_X360) unsigned char pad; #endif int m_nTab; int m_nMaxPut; int m_nOffset; UtlBufferOverflowFunc_t m_GetOverflowFunc; UtlBufferOverflowFunc_t m_PutOverflowFunc; CByteswap m_Byteswap; }; // Stream style output operators for CUtlBuffer inline CUtlBuffer &operator<<(CUtlBuffer &b, char v) { b.PutChar(v); return b; } inline CUtlBuffer &operator<<(CUtlBuffer &b, unsigned char v) { b.PutUnsignedChar(v); return b; } inline CUtlBuffer &operator<<(CUtlBuffer &b, short v) { b.PutShort(v); return b; } inline CUtlBuffer &operator<<(CUtlBuffer &b, unsigned short v) { b.PutUnsignedShort(v); return b; } inline CUtlBuffer &operator<<(CUtlBuffer &b, int v) { b.PutInt(v); return b; } inline CUtlBuffer &operator<<(CUtlBuffer &b, unsigned int v) { b.PutUnsignedInt(v); return b; } inline CUtlBuffer &operator<<(CUtlBuffer &b, float v) { b.PutFloat(v); return b; } inline CUtlBuffer &operator<<(CUtlBuffer &b, double v) { b.PutDouble(v); return b; } inline CUtlBuffer &operator<<(CUtlBuffer &b, const char *pv) { b.PutString(pv); return b; } inline CUtlBuffer &operator<<(CUtlBuffer &b, const Vector &v) { b << v.x << " " << v.y << " " << v.z; return b; } inline CUtlBuffer &operator<<(CUtlBuffer &b, const Vector2D &v) { b << v.x << " " << v.y; return b; } class CUtlInplaceBuffer : public CUtlBuffer { public: CUtlInplaceBuffer(int growSize = 0, int initSize = 0, int nFlags = 0); // // Routines returning buffer-inplace-pointers // public: // // Upon success, determines the line length, fills out the pointer to the // beginning of the line and the line length, advances the "get" pointer // offset by the line length and returns "true". // // If end of file is reached or upon error returns "false". // // Note: the returned length of the line is at least one character because // the // trailing newline characters are also included as part of the //line. // // Note: the pointer returned points into the local memory of this buffer, // in // case the buffer gets relocated or destroyed the pointer becomes //invalid. // // e.g.: ------------- // // char *pszLine; // int nLineLen; // while ( pUtlInplaceBuffer->InplaceGetLinePtr( &pszLine, &nLineLen ) //) // { // ... // } // // ------------- // // @param ppszInBufferPtr on return points into this buffer at start of // line // @param pnLineLength on return holds num bytes accessible via // (*ppszInBufferPtr) // // @returns true if line was successfully read // false when EOF is reached or error //occurs // bool InplaceGetLinePtr(/* out */ char **ppszInBufferPtr, /* out */ int *pnLineLength); // // Determines the line length, advances the "get" pointer offset by the line // length, replaces the newline character with null-terminator and returns // the initial pointer to now null-terminated line. // // If end of file is reached or upon error returns NULL. // // Note: the pointer returned points into the local memory of this buffer, // in // case the buffer gets relocated or destroyed the pointer becomes //invalid. // // e.g.: ------------- // // while ( char *pszLine = pUtlInplaceBuffer->InplaceGetLinePtr() //) // { // ... // } // // ------------- // // @returns ptr-to-zero-terminated-line if line was successfully read and // buffer modified // NULL when EOF is reached or error //occurs // char *InplaceGetLinePtr(void); }; //----------------------------------------------------------------------------- // Where am I reading? //----------------------------------------------------------------------------- inline int CUtlBuffer::TellGet() const { return m_Get; } //----------------------------------------------------------------------------- // How many bytes remain to be read? //----------------------------------------------------------------------------- inline int CUtlBuffer::GetBytesRemaining() const { return m_nMaxPut - TellGet(); } //----------------------------------------------------------------------------- // What am I reading? //----------------------------------------------------------------------------- inline const void *CUtlBuffer::PeekGet(int offset) const { return &m_Memory[m_Get + offset - m_nOffset]; } //----------------------------------------------------------------------------- // Unserialization //----------------------------------------------------------------------------- template inline void CUtlBuffer::GetObject(T *dest) { if (CheckGet(sizeof(T))) { if (!m_Byteswap.IsSwappingBytes() || (sizeof(T) == 1)) { *dest = *(T *)PeekGet(); } else { m_Byteswap.SwapFieldsToTargetEndian(dest, (T *)PeekGet()); } m_Get += sizeof(T); } else { Q_memset(dest, 0, sizeof(T)); } } template inline void CUtlBuffer::GetObjects(T *dest, int count) { for (int i = 0; i < count; ++i, ++dest) { GetObject(dest); } } template inline void CUtlBuffer::GetTypeBin(T &dest) { if (CheckGet(sizeof(T))) { if (!m_Byteswap.IsSwappingBytes() || (sizeof(T) == 1)) { dest = *(T *)PeekGet(); } else { m_Byteswap.SwapBufferToTargetEndian(&dest, (T *)PeekGet()); } m_Get += sizeof(T); } else { dest = 0; } } template <> inline void CUtlBuffer::GetTypeBin(float &dest) { if (CheckGet(sizeof(float))) { uintptr_t pData = (uintptr_t)PeekGet(); if (IsX360() && (pData & 0x03)) { // handle unaligned read ((unsigned char *)&dest)[0] = ((unsigned char *)pData)[0]; ((unsigned char *)&dest)[1] = ((unsigned char *)pData)[1]; ((unsigned char *)&dest)[2] = ((unsigned char *)pData)[2]; ((unsigned char *)&dest)[3] = ((unsigned char *)pData)[3]; } else { // aligned read dest = *(float *)pData; } if (m_Byteswap.IsSwappingBytes()) { m_Byteswap.SwapBufferToTargetEndian(&dest, &dest); } m_Get += sizeof(float); } else { dest = 0; } } template inline void CUtlBuffer::GetType(T &dest, const char *pszFmt) { if (!IsText()) { GetTypeBin(dest); } else { dest = 0; Scanf(pszFmt, &dest); } } inline char CUtlBuffer::GetChar() { char c; GetType(c, "%c"); return c; } inline unsigned char CUtlBuffer::GetUnsignedChar() { unsigned char c; GetType(c, "%u"); return c; } inline short CUtlBuffer::GetShort() { short s; GetType(s, "%d"); return s; } inline unsigned short CUtlBuffer::GetUnsignedShort() { unsigned short s; GetType(s, "%u"); return s; } inline int CUtlBuffer::GetInt() { int i; GetType(i, "%d"); return i; } inline int64 CUtlBuffer::GetInt64() { int64 i; GetType(i, "%lld"); return i; } inline int CUtlBuffer::GetIntHex() { int i; GetType(i, "%x"); return i; } inline unsigned int CUtlBuffer::GetUnsignedInt() { unsigned int u; GetType(u, "%u"); return u; } inline float CUtlBuffer::GetFloat() { float f; GetType(f, "%f"); return f; } inline double CUtlBuffer::GetDouble() { double d; GetType(d, "%f"); return d; } //----------------------------------------------------------------------------- // Where am I writing? //----------------------------------------------------------------------------- inline unsigned char CUtlBuffer::GetFlags() const { return m_Flags; } //----------------------------------------------------------------------------- // //----------------------------------------------------------------------------- inline bool CUtlBuffer::IsExternallyAllocated() const { return m_Memory.IsExternallyAllocated(); } //----------------------------------------------------------------------------- // Where am I writing? //----------------------------------------------------------------------------- inline int CUtlBuffer::TellPut() const { return m_Put; } //----------------------------------------------------------------------------- // What's the most I've ever written? //----------------------------------------------------------------------------- inline int CUtlBuffer::TellMaxPut() const { return m_nMaxPut; } //----------------------------------------------------------------------------- // What am I reading? //----------------------------------------------------------------------------- inline void *CUtlBuffer::PeekPut(int offset) { return &m_Memory[m_Put + offset - m_nOffset]; } //----------------------------------------------------------------------------- // Various put methods //----------------------------------------------------------------------------- template inline void CUtlBuffer::PutObject(T *src) { if (CheckPut(sizeof(T))) { if (!m_Byteswap.IsSwappingBytes() || (sizeof(T) == 1)) { *(T *)PeekPut() = *src; } else { m_Byteswap.SwapFieldsToTargetEndian((T *)PeekPut(), src); } m_Put += sizeof(T); AddNullTermination(); } } template inline void CUtlBuffer::PutObjects(T *src, int count) { for (int i = 0; i < count; ++i, ++src) { PutObject(src); } } template inline void CUtlBuffer::PutTypeBin(T src) { if (CheckPut(sizeof(T))) { if (!m_Byteswap.IsSwappingBytes() || (sizeof(T) == 1)) { *(T *)PeekPut() = src; } else { m_Byteswap.SwapBufferToTargetEndian((T *)PeekPut(), &src); } m_Put += sizeof(T); AddNullTermination(); } } template inline void CUtlBuffer::PutType(T src, const char *pszFmt) { if (!IsText()) { PutTypeBin(src); } else { Printf(pszFmt, src); } } //----------------------------------------------------------------------------- // Methods to help with pretty-printing //----------------------------------------------------------------------------- inline bool CUtlBuffer::WasLastCharacterCR() { if (!IsText() || (TellPut() == 0)) return false; return (*(const char *)PeekPut(-1) == '\n'); } inline void CUtlBuffer::PutTabs() { int nTabCount = (m_Flags & AUTO_TABS_DISABLED) ? 0 : m_nTab; for (int i = nTabCount; --i >= 0;) { PutTypeBin('\t'); } } //----------------------------------------------------------------------------- // Push/pop pretty-printing tabs //----------------------------------------------------------------------------- inline void CUtlBuffer::PushTab() { ++m_nTab; } inline void CUtlBuffer::PopTab() { if (--m_nTab < 0) { m_nTab = 0; } } //----------------------------------------------------------------------------- // Temporarily disables pretty print //----------------------------------------------------------------------------- inline void CUtlBuffer::EnableTabs(bool bEnable) { if (bEnable) { m_Flags &= ~AUTO_TABS_DISABLED; } else { m_Flags |= AUTO_TABS_DISABLED; } } inline void CUtlBuffer::PutChar(char c) { if (WasLastCharacterCR()) { PutTabs(); } PutTypeBin(c); } inline void CUtlBuffer::PutUnsignedChar(unsigned char c) { PutType(c, "%u"); } inline void CUtlBuffer::PutUint64(uint64 ub) { PutType(ub, "%llu"); } inline void CUtlBuffer::PutInt16(int16 s16) { PutType(s16, "%d"); } inline void CUtlBuffer::PutShort(short s) { PutType(s, "%d"); } inline void CUtlBuffer::PutUnsignedShort(unsigned short s) { PutType(s, "%u"); } inline void CUtlBuffer::PutInt(int i) { PutType(i, "%d"); } inline void CUtlBuffer::PutInt64(int64 i) { PutType(i, "%llu"); } inline void CUtlBuffer::PutUnsignedInt(unsigned int u) { PutType(u, "%u"); } inline void CUtlBuffer::PutFloat(float f) { PutType(f, "%f"); } inline void CUtlBuffer::PutDouble(double d) { PutType(d, "%f"); } //----------------------------------------------------------------------------- // Am I a text buffer? //----------------------------------------------------------------------------- inline bool CUtlBuffer::IsText() const { return (m_Flags & TEXT_BUFFER) != 0; } //----------------------------------------------------------------------------- // Can I grow if I'm externally allocated? //----------------------------------------------------------------------------- inline bool CUtlBuffer::IsGrowable() const { return (m_Flags & EXTERNAL_GROWABLE) != 0; } //----------------------------------------------------------------------------- // Am I valid? (overflow or underflow error), Once invalid it stays invalid //----------------------------------------------------------------------------- inline bool CUtlBuffer::IsValid() const { return m_Error == 0; } //----------------------------------------------------------------------------- // Do I contain carriage return/linefeeds? //----------------------------------------------------------------------------- inline bool CUtlBuffer::ContainsCRLF() const { return IsText() && ((m_Flags & CONTAINS_CRLF) != 0); } //----------------------------------------------------------------------------- // Am I read-only //----------------------------------------------------------------------------- inline bool CUtlBuffer::IsReadOnly() const { return (m_Flags & READ_ONLY) != 0; } //----------------------------------------------------------------------------- // Buffer base and size //----------------------------------------------------------------------------- inline const void *CUtlBuffer::Base() const { return m_Memory.Base(); } inline void *CUtlBuffer::Base() { return m_Memory.Base(); } // Returns the base as a const char*, only valid in text mode. inline const char *CUtlBuffer::String() const { Assert(IsText()); return reinterpret_cast(m_Memory.Base()); } inline int CUtlBuffer::Size() const { return m_Memory.NumAllocated(); } //----------------------------------------------------------------------------- // Clears out the buffer; frees memory //----------------------------------------------------------------------------- inline void CUtlBuffer::Clear() { m_Get = 0; m_Put = 0; m_Error = 0; m_nOffset = 0; m_nMaxPut = -1; AddNullTermination(); } inline void CUtlBuffer::Purge() { m_Get = 0; m_Put = 0; m_nOffset = 0; m_nMaxPut = 0; m_Error = 0; m_Memory.Purge(); } inline void CUtlBuffer::CopyBuffer(const CUtlBuffer &buffer) { CopyBuffer(buffer.Base(), buffer.TellPut()); } inline void CUtlBuffer::CopyBuffer(const void *pubData, int cubData) { Clear(); if (cubData) { Put(pubData, cubData); } } #endif // UTLBUFFER_H