windows-nt/Source/XPSP1/NT/enduser/netmeeting/nmutil/cstring.cpp
2020-09-26 16:20:57 +08:00

681 lines
16 KiB
C++

// CSTRING.CPP
//
// Based on the original MFC source file.
//
// This is a part of the Microsoft Foundation Classes C++ library.
// Copyright (C) 1992-1995 Microsoft Corporation
// All rights reserved.
//
// This source code is only intended as a supplement to the
// Microsoft Foundation Classes Reference and related
// electronic documentation provided with the library.
// See these sources for detailed information regarding the
// Microsoft Foundation Classes product.
#include "precomp.h"
#include <cstring.hpp>
#ifdef AFX_CORE1_SEG
#pragma code_seg(AFX_CORE1_SEG)
#endif
#ifdef _DEBUG
#undef THIS_FILE
static char THIS_FILE[] = __FILE__;
#endif
/////////////////////////////////////////////////////////////////////////////
// static class data, special inlines
// afxChNil is left for backward compatibility
REMAFX_DATADEF TCHAR AFXChNil = '\0';
// For an empty string, m_pchData will point here
// (note: avoids special case of checking for NULL m_pchData)
// empty string data (and locked)
static int RGInitData[] = { -1, 0, 0, 0 };
static REMAFX_DATADEF CSTRINGData* AFXDataNil = (CSTRINGData*)&RGInitData;
static LPCTSTR AFXPchNil = (LPCTSTR)(((BYTE*)&RGInitData)+sizeof(CSTRINGData));
// special function to make AFXEmptyString work even during initialization
const CSTRING& REMAFXAPI AFXGetEmptyString()
{ return *(CSTRING*)&AFXPchNil; }
//////////////////////////////////////////////////////////////////////////////
// Construction/Destruction
CSTRING::CSTRING()
{
Init();
}
CSTRING::CSTRING(const CSTRING& stringSrc)
{
ASSERT(stringSrc.GetData()->nRefs != 0);
if (stringSrc.GetData()->nRefs >= 0)
{
ASSERT(stringSrc.GetData() != AFXDataNil);
m_pchData = stringSrc.m_pchData;
InterlockedIncrement(&GetData()->nRefs);
}
else
{
Init();
*this = stringSrc.m_pchData;
}
}
CSTRING::CSTRING(LPCTSTR lpch, int nLength)
{
Init();
if (nLength != 0)
{
// ASSERT(AfxIsValidAddress(lpch, nLength, FALSE));
AllocBuffer(nLength);
memcpy(m_pchData, lpch, nLength*sizeof(TCHAR));
}
}
void CSTRING::AllocBuffer(int nLen)
// always allocate one extra character for '\0' termination
// assumes [optimistically] that data length will equal allocation length
{
ASSERT(nLen >= 0);
ASSERT(nLen <= INT_MAX-1); // max size (enough room for 1 extra)
if (nLen == 0)
Init();
else
{
CSTRINGData* pData =
(CSTRINGData*)new BYTE[sizeof(CSTRINGData) + (nLen+1)*sizeof(TCHAR)];
pData->nRefs = 1;
pData->data()[nLen] = '\0';
pData->nDataLength = nLen;
pData->nAllocLength = nLen;
m_pchData = pData->data();
}
}
void CSTRING::Release()
{
if (GetData() != AFXDataNil)
{
ASSERT(GetData()->nRefs != 0);
if (InterlockedDecrement(&GetData()->nRefs) <= 0)
delete[] (BYTE*)GetData();
Init();
}
}
void PASCAL CSTRING::Release(CSTRINGData* pData)
{
if (pData != AFXDataNil)
{
ASSERT(pData->nRefs != 0);
if (InterlockedDecrement(&pData->nRefs) <= 0)
delete[] (BYTE*)pData;
}
}
void CSTRING::Empty()
{
if (GetData()->nRefs >= 0)
Release();
else
*this = &AFXChNil;
ASSERT(GetData()->nDataLength == 0);
ASSERT(GetData()->nRefs < 0 || GetData()->nAllocLength == 0);
}
void CSTRING::CopyBeforeWrite()
{
if (GetData()->nRefs > 1)
{
CSTRINGData* pData = GetData();
Release();
AllocBuffer(pData->nDataLength);
memcpy(m_pchData, pData->data(), (pData->nDataLength+1)*sizeof(TCHAR));
}
ASSERT(GetData()->nRefs <= 1);
}
void CSTRING::AllocBeforeWrite(int nLen)
{
if (GetData()->nRefs > 1 || nLen > GetData()->nAllocLength)
{
Release();
AllocBuffer(nLen);
}
ASSERT(GetData()->nRefs <= 1);
}
CSTRING::~CSTRING()
// free any attached data
{
if (GetData() != AFXDataNil)
{
if (InterlockedDecrement(&GetData()->nRefs) <= 0)
delete[] (BYTE*)GetData();
}
}
//////////////////////////////////////////////////////////////////////////////
// Helpers for the rest of the implementation
void CSTRING::AllocCopy(CSTRING& dest, int nCopyLen, int nCopyIndex,
int nExtraLen) const
{
// will clone the data attached to this string
// allocating 'nExtraLen' characters
// Places results in uninitialized string 'dest'
// Will copy the part or all of original data to start of new string
int nNewLen = nCopyLen + nExtraLen;
if (nNewLen == 0)
{
dest.Init();
}
else
{
dest.AllocBuffer(nNewLen);
memcpy(dest.m_pchData, m_pchData+nCopyIndex, nCopyLen*sizeof(TCHAR));
}
}
//////////////////////////////////////////////////////////////////////////////
// More sophisticated construction
CSTRING::CSTRING(LPCTSTR lpsz)
{
Init();
// if (lpsz != NULL && HIWORD(lpsz) == NULL)
// {
// UINT nID = LOWORD((DWORD)lpsz);
// if (!LoadString(nID)) {
// ;// TRACE1("Warning: implicit LoadString(%u) failed\n", nID);
// }
// }
// else
{
int nLen = SafeStrlen(lpsz);
if (nLen != 0)
{
AllocBuffer(nLen);
memcpy(m_pchData, lpsz, nLen*sizeof(TCHAR));
}
}
}
/////////////////////////////////////////////////////////////////////////////
// Special conversion constructors
#ifdef _UNICODE
CSTRING::CSTRING(LPCSTR lpsz)
{
Init();
int nSrcLen = lpsz != NULL ? lstrlenA(lpsz) : 0;
if (nSrcLen != 0)
{
AllocBuffer(nSrcLen);
_mbstowcsz(m_pchData, lpsz, nSrcLen+1);
ReleaseBuffer();
}
}
#else //_UNICODE
CSTRING::CSTRING(LPCWSTR lpsz)
{
Init();
int nSrcLen = lpsz != NULL ? LStrLenW(lpsz) : 0;
if (nSrcLen != 0)
{
AllocBuffer(nSrcLen*2);
_wcstombsz(m_pchData, lpsz, (nSrcLen*2)+1);
ReleaseBuffer();
}
}
#endif //!_UNICODE
//////////////////////////////////////////////////////////////////////////////
// Diagnostic support
//#ifdef _DEBUG
//CDumpContext& REMAFXAPI operator<<(CDumpContext& dc, const CSTRING& string)
//{
// dc << string.m_pchData;
// return dc;
//}
//#endif //_DEBUG
//////////////////////////////////////////////////////////////////////////////
// Assignment operators
// All assign a new value to the string
// (a) first see if the buffer is big enough
// (b) if enough room, copy on top of old buffer, set size and type
// (c) otherwise free old string data, and create a new one
//
// All routines return the new string (but as a 'const CSTRING&') so that
// assigning it again will cause a copy, eg: s1 = s2 = "hi there".
//
void CSTRING::AssignCopy(int nSrcLen, LPCTSTR lpszSrcData)
{
AllocBeforeWrite(nSrcLen);
memcpy(m_pchData, lpszSrcData, nSrcLen*sizeof(TCHAR));
GetData()->nDataLength = nSrcLen;
m_pchData[nSrcLen] = '\0';
}
const CSTRING& CSTRING::operator=(const CSTRING& stringSrc)
{
if (m_pchData != stringSrc.m_pchData)
{
if ((GetData()->nRefs < 0 && GetData() != AFXDataNil) ||
stringSrc.GetData()->nRefs < 0)
{
// actual copy necessary since one of the strings is locked
AssignCopy(stringSrc.GetData()->nDataLength, stringSrc.m_pchData);
}
else
{
// can just copy references around
Release();
ASSERT(stringSrc.GetData() != AFXDataNil);
m_pchData = stringSrc.m_pchData;
InterlockedIncrement(&GetData()->nRefs);
}
}
return *this;
}
const CSTRING& CSTRING::operator=(LPCTSTR lpsz)
{
//lts ASSERT(lpsz == NULL || AfxIsValidString(lpsz, FALSE));
AssignCopy(SafeStrlen(lpsz), lpsz);
return *this;
}
/////////////////////////////////////////////////////////////////////////////
// Special conversion assignment
#ifdef _UNICODE
const CSTRING& CSTRING::operator=(LPCSTR lpsz)
{
int nSrcLen = lpsz != NULL ? lstrlenA(lpsz) : 0;
AllocBeforeWrite(nSrcLen);
_mbstowcsz(m_pchData, lpsz, nSrcLen+1);
ReleaseBuffer();
return *this;
}
#else //!_UNICODE
const CSTRING& CSTRING::operator=(LPCWSTR lpsz)
{
int nSrcLen = lpsz != NULL ? LStrLenW(lpsz) : 0;
AllocBeforeWrite(nSrcLen*2);
_wcstombsz(m_pchData, lpsz, (nSrcLen*2)+1);
ReleaseBuffer();
return *this;
}
#endif //!_UNICODE
//////////////////////////////////////////////////////////////////////////////
// concatenation
// NOTE: "operator+" is done as friend functions for simplicity
// There are three variants:
// CSTRING + CSTRING
// and for ? = TCHAR, LPCTSTR
// CSTRING + ?
// ? + CSTRING
void CSTRING::ConcatCopy(int nSrc1Len, LPCTSTR lpszSrc1Data,
int nSrc2Len, LPCTSTR lpszSrc2Data)
{
// -- master concatenation routine
// Concatenate two sources
// -- assume that 'this' is a new CSTRING object
int nNewLen = nSrc1Len + nSrc2Len;
if (nNewLen != 0)
{
AllocBuffer(nNewLen);
memcpy(m_pchData, lpszSrc1Data, nSrc1Len*sizeof(TCHAR));
memcpy(m_pchData+nSrc1Len, lpszSrc2Data, nSrc2Len*sizeof(TCHAR));
}
}
CSTRING REMAFXAPI operator+(const CSTRING& string1, const CSTRING& string2)
{
CSTRING s;
s.ConcatCopy(string1.GetData()->nDataLength, string1.m_pchData,
string2.GetData()->nDataLength, string2.m_pchData);
return s;
}
CSTRING REMAFXAPI operator+(const CSTRING& string, LPCTSTR lpsz)
{
// ASSERT(lpsz == NULL || AfxIsValidString(lpsz, FALSE));
CSTRING s;
s.ConcatCopy(string.GetData()->nDataLength, string.m_pchData,
CSTRING::SafeStrlen(lpsz), lpsz);
return s;
}
CSTRING REMAFXAPI operator+(LPCTSTR lpsz, const CSTRING& string)
{
// ASSERT(lpsz == NULL || AfxIsValidString(lpsz, FALSE));
CSTRING s;
s.ConcatCopy(CSTRING::SafeStrlen(lpsz), lpsz, string.GetData()->nDataLength,
string.m_pchData);
return s;
}
//////////////////////////////////////////////////////////////////////////////
// concatenate in place
void CSTRING::ConcatInPlace(int nSrcLen, LPCTSTR lpszSrcData)
{
// -- the main routine for += operators
// if the buffer is too small, or we have a width mis-match, just
// allocate a new buffer (slow but sure)
if (GetData()->nRefs > 1 || GetData()->nDataLength + nSrcLen > GetData()->nAllocLength)
{
// we have to grow the buffer, use the ConcatCopy routine
CSTRINGData* pOldData = GetData();
ConcatCopy(GetData()->nDataLength, m_pchData, nSrcLen, lpszSrcData);
ASSERT(pOldData != NULL);
CSTRING::Release(pOldData);
}
else
{
// fast concatenation when buffer big enough
memcpy(m_pchData+GetData()->nDataLength, lpszSrcData, nSrcLen*sizeof(TCHAR));
GetData()->nDataLength += nSrcLen;
ASSERT(GetData()->nDataLength <= GetData()->nAllocLength);
m_pchData[GetData()->nDataLength] = '\0';
}
}
const CSTRING& CSTRING::operator+=(LPCTSTR lpsz)
{
// ASSERT(lpsz == NULL || AfxIsValidString(lpsz, FALSE));
ConcatInPlace(SafeStrlen(lpsz), lpsz);
return *this;
}
const CSTRING& CSTRING::operator+=(TCHAR ch)
{
ConcatInPlace(1, &ch);
return *this;
}
const CSTRING& CSTRING::operator+=(const CSTRING& string)
{
ConcatInPlace(string.GetData()->nDataLength, string.m_pchData);
return *this;
}
/*
* Length-sensitive comparison
*
* NOTE: FEqual returns TRUE if the 2 CSTRINGS have the same length and contain
* the same characters, and FALSE, otherwise.
*/
BOOL CSTRING::FEqual (const CSTRING &s2) const
{
int length;
// Compare the lengths first
length = GetData()->nDataLength;
if (length != s2.GetData()->nDataLength)
return FALSE;
#ifdef _UNICODE
// adjust the length in bytes
length *= sizeof (TCHAR);
#endif
/*
* Now, compare the strings themselves
* We use memcmp and not lstrcmp because the stings may
* have embedded null characters.
*/
if (memcmp ((const void *) m_pchData, (const void *) s2.m_pchData, length))
return FALSE;
else
return TRUE;
}
///////////////////////////////////////////////////////////////////////////////
// Advanced direct buffer access
LPTSTR CSTRING::GetBuffer(int nMinBufLength)
{
ASSERT(nMinBufLength >= 0);
if (GetData()->nRefs > 1 || nMinBufLength > GetData()->nAllocLength)
{
// we have to grow the buffer
CSTRINGData* pOldData = GetData();
int nOldLen = GetData()->nDataLength; // AllocBuffer will tromp it
if (nMinBufLength < nOldLen)
nMinBufLength = nOldLen;
AllocBuffer(nMinBufLength);
memcpy(m_pchData, pOldData->data(), (nOldLen+1)*sizeof(TCHAR));
GetData()->nDataLength = nOldLen;
CSTRING::Release(pOldData);
}
ASSERT(GetData()->nRefs <= 1);
// return a pointer to the character storage for this string
ASSERT(m_pchData != NULL);
return m_pchData;
}
void CSTRING::ReleaseBuffer(int nNewLength)
{
CopyBeforeWrite(); // just in case GetBuffer was not called
if (nNewLength == -1)
nNewLength = lstrlen(m_pchData); // zero terminated
ASSERT(nNewLength <= GetData()->nAllocLength);
GetData()->nDataLength = nNewLength;
m_pchData[nNewLength] = '\0';
}
LPTSTR CSTRING::GetBufferSetLength(int nNewLength)
{
ASSERT(nNewLength >= 0);
GetBuffer(nNewLength);
GetData()->nDataLength = nNewLength;
m_pchData[nNewLength] = '\0';
return m_pchData;
}
void CSTRING::FreeExtra()
{
ASSERT(GetData()->nDataLength <= GetData()->nAllocLength);
if (GetData()->nDataLength != GetData()->nAllocLength)
{
CSTRINGData* pOldData = GetData();
AllocBuffer(GetData()->nDataLength);
memcpy(m_pchData, pOldData->data(), pOldData->nDataLength*sizeof(TCHAR));
ASSERT(m_pchData[GetData()->nDataLength] == '\0');
CSTRING::Release(pOldData);
}
ASSERT(GetData() != NULL);
}
LPTSTR CSTRING::LockBuffer()
{
LPTSTR lpsz = GetBuffer(0);
GetData()->nRefs = -1;
return lpsz;
}
void CSTRING::UnlockBuffer()
{
ASSERT(GetData()->nRefs == -1);
if (GetData() != AFXDataNil)
GetData()->nRefs = 1;
}
///////////////////////////////////////////////////////////////////////////////
// Commonly used routines (rarely used routines in STREX.CPP)
// find position of the first character match (or -1 on failure)
int CSTRING::Find(TCHAR ch) const
{
for (TCHAR * pch = m_pchData; _T('\0') != *pch; pch = CharNext(pch))
{
if (ch == *pch)
return ((int)(pch - m_pchData) / sizeof(TCHAR));
}
return -1;
}
CSTRING CSTRING::Left(int nCount) const
{
if (nCount < 0)
nCount = 0;
else if (nCount > GetData()->nDataLength)
nCount = GetData()->nDataLength;
CSTRING dest;
AllocCopy(dest, nCount, 0, 0);
return dest;
}
CSTRING CSTRING::Mid(int nFirst) const
{
return Mid(nFirst, GetData()->nDataLength - nFirst);
}
CSTRING CSTRING::Mid(int nFirst, int nCount) const
{
// out-of-bounds requests return sensible things
if (nFirst < 0)
nFirst = 0;
if (nCount < 0)
nCount = 0;
if (nFirst + nCount > GetData()->nDataLength)
nCount = GetData()->nDataLength - nFirst;
if (nFirst > GetData()->nDataLength)
nCount = 0;
CSTRING dest;
AllocCopy(dest, nCount, nFirst, 0);
return dest;
}
void CSTRING::MakeUpper()
{
CopyBeforeWrite();
::CharUpper(m_pchData);
}
void CSTRING::MakeLower()
{
CopyBeforeWrite();
::CharLower(m_pchData);
}
void CSTRING::SetAt(int nIndex, TCHAR ch)
{
ASSERT(nIndex >= 0);
ASSERT(nIndex < GetData()->nDataLength);
CopyBeforeWrite();
m_pchData[nIndex] = ch;
}
#ifndef _UNICODE
void CSTRING::AnsiToOem()
{
CopyBeforeWrite();
::AnsiToOem(m_pchData, m_pchData);
}
#endif
///////////////////////////////////////////////////////////////////////////////
// CSTRING conversion helpers (these use the current system locale)
int REMAFX_CDECL _wcstombsz(char* mbstr, const wchar_t* wcstr, size_t count)
{
if (count == 0 && mbstr != NULL)
return 0;
int result = ::WideCharToMultiByte(CP_ACP, 0, wcstr, -1,
mbstr, count, NULL, NULL);
ASSERT(mbstr == NULL || result <= (int)count);
if (result > 0)
mbstr[result-1] = 0;
return result;
}
int REMAFX_CDECL _mbstowcsz(wchar_t* wcstr, const char* mbstr, size_t count)
{
if (count == 0 && wcstr != NULL)
return 0;
int result = ::MultiByteToWideChar(CP_ACP, 0, mbstr, -1,
wcstr, count);
ASSERT(wcstr == NULL || result <= (int)count);
if (result > 0)
wcstr[result-1] = 0;
return result;
}
LPWSTR REMAFXAPI AfxA2WHelper(LPWSTR lpw, LPCSTR lpa, int nChars)
{
if (lpa == NULL)
return NULL;
ASSERT(lpw != NULL);
// verify that no illegal character present
// since lpw was allocated based on the size of lpa
// don't worry about the number of chars
lpw[0] = '\0';
//lts VERIFY(MultiByteToWideChar(CP_ACP, 0, lpa, -1, lpw, nChars));
MultiByteToWideChar(CP_ACP, 0, lpa, -1, lpw, nChars);
return lpw;
}
LPSTR REMAFXAPI AfxW2AHelper(LPSTR lpa, LPCWSTR lpw, int nChars)
{
if (lpw == NULL)
return NULL;
ASSERT(lpa != NULL);
// verify that no illegal character present
// since lpa was allocated based on the size of lpw
// don't worry about the number of chars
lpa[0] = '\0';
//lts VERIFY(WideCharToMultiByte(CP_ACP, 0, lpw, -1, lpa, nChars, NULL, NULL));
WideCharToMultiByte(CP_ACP, 0, lpw, -1, lpa, nChars, NULL, NULL);
return lpa;
}
///////////////////////////////////////////////////////////////////////////////
BOOL CSTRING::LoadString(HINSTANCE hInstance, UINT nID)
{
// try buffer size of 256, then larger size until entire string is retrieved
int nSize = -1;
int nLen;
do
{
nSize += 256;
nLen = ::LoadString(hInstance, nID, GetBuffer(nSize), nSize+1);
} while (nLen == nSize);
ReleaseBuffer();
return nLen > 0;
}