windows-nt/Source/XPSP1/NT/multimedia/dshow/vidctl/atl/atltmp.h

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2020-09-26 03:20:57 -05:00
// This is a part of the Active Template Library.
// Copyright (C) 1996-1998 Microsoft Corporation
// All rights reserved.
//
// This source code is only intended as a supplement to the
// Active Template Library Reference and related
// electronic documentation provided with the library.
// See these sources for detailed information regarding the
// Active Template Library product.
// atltmp.h - temporary location for these classes
#ifndef __ATLTMP_H__
#define __ATLTMP_H__
#ifndef __cplusplus
#error ATL requires C++ compilation (use a .cpp suffix)
#endif
#ifndef __ATLBASE_H__
#error atltmp.h requires atlbase.h to be included first
#endif
#pragma once
#ifndef _ATL_TMP_NO_CSTRING
#include <limits.h>
#include <stdio.h>
#endif //!_ATL_TMP_NO_CSTRING
namespace ATL
{
/////////////////////////////////////////////////////////////////////////////
// Forward declarations
class CSize;
class CPoint;
class CRect;
#ifndef _ATL_TMP_NO_CSTRING
class CString;
#endif //!_ATL_TMP_NO_CSTRING
/////////////////////////////////////////////////////////////////////////////
// CSize - An extent, similar to Windows SIZE structure.
class CSize : public tagSIZE
{
public:
// Constructors
CSize();
CSize(int initCX, int initCY);
CSize(SIZE initSize);
CSize(POINT initPt);
CSize(DWORD dwSize);
// Operations
BOOL operator==(SIZE size) const;
BOOL operator!=(SIZE size) const;
void operator+=(SIZE size);
void operator-=(SIZE size);
bool operator!() { return !cx && !cy; }
// Operators returning CSize values
CSize operator+(SIZE size) const;
CSize operator-(SIZE size) const;
CSize operator-() const;
// Operators returning CPoint values
CPoint operator+(POINT point) const;
CPoint operator-(POINT point) const;
// Operators returning CRect values
CRect operator+(const RECT* lpRect) const;
CRect operator-(const RECT* lpRect) const;
};
/////////////////////////////////////////////////////////////////////////////
// CPoint - A 2-D point, similar to Windows POINT structure.
class CPoint : public tagPOINT
{
public:
// Constructors
CPoint() {
x = 0;
y = 0;
}
CPoint(int initX, int initY);
CPoint(POINT initPt);
CPoint(SIZE initSize);
CPoint(DWORD dwPoint);
// Operations
void Offset(int xOffset, int yOffset);
void Offset(POINT point);
void Offset(SIZE size);
BOOL operator==(POINT point) const;
BOOL operator!=(POINT point) const;
void operator+=(SIZE size);
void operator-=(SIZE size);
void operator+=(POINT point);
void operator-=(POINT point);
bool operator!() { return !x && !y; }
// Operators returning CPoint values
CPoint operator+(SIZE size) const;
CPoint operator-(SIZE size) const;
CPoint operator-() const;
CPoint operator+(POINT point) const;
// Operators returning CSize values
CSize operator-(POINT point) const;
// Operators returning CRect values
CRect operator+(const RECT* lpRect) const;
CRect operator-(const RECT* lpRect) const;
};
/////////////////////////////////////////////////////////////////////////////
// CRect - A 2-D rectangle, similar to Windows RECT structure.
//typedef const RECT* LPCRECT; // pointer to read/only RECT
class CRect : public tagRECT
{
public:
// Constructors
CRect() {
left = 0;
top = 0;
right = 0;
bottom = 0;
}
CRect(int l, int t, int r, int b);
CRect(const RECT& srcRect);
CRect(LPCRECT lpSrcRect);
CRect(POINT point, SIZE size);
CRect(POINT topLeft, POINT bottomRight);
// Attributes (in addition to RECT members)
int Width() const;
int Height() const;
CSize Size() const;
CPoint& TopLeft();
CPoint& BottomRight();
const CPoint& TopLeft() const;
const CPoint& BottomRight() const;
CPoint CenterPoint() const;
// convert between CRect and LPRECT/LPCRECT (no need for &)
operator LPRECT();
operator LPCRECT() const;
BOOL IsRectEmpty() const;
BOOL IsRectNull() const;
BOOL PtInRect(POINT point) const;
// Operations
void SetRect(int x1, int y1, int x2, int y2);
void SetRect(POINT topLeft, POINT bottomRight);
void SetRectEmpty();
void CopyRect(LPCRECT lpSrcRect);
BOOL EqualRect(LPCRECT lpRect) const;
void InflateRect(int x, int y);
void InflateRect(SIZE size);
void InflateRect(LPCRECT lpRect);
void InflateRect(int l, int t, int r, int b);
void DeflateRect(int x, int y);
void DeflateRect(SIZE size);
void DeflateRect(LPCRECT lpRect);
void DeflateRect(int l, int t, int r, int b);
void OffsetRect(int x, int y);
void OffsetRect(SIZE size);
void OffsetRect(POINT point);
void NormalizeRect();
// operations that fill '*this' with result
BOOL IntersectRect(LPCRECT lpRect1, LPCRECT lpRect2);
BOOL IntersectRect(LPCRECT lpRect2); // use this for rect1
BOOL UnionRect(LPCRECT lpRect1, LPCRECT lpRect2);
BOOL SubtractRect(LPCRECT lpRectSrc1, LPCRECT lpRectSrc2);
// Additional Operations
void operator=(const RECT& srcRect);
BOOL operator==(const RECT& rect) const;
BOOL operator!=(const RECT& rect) const;
bool operator!() { return !left && !top && !right && !bottom; }
void operator+=(POINT point);
void operator+=(SIZE size);
void operator+=(LPCRECT lpRect);
void operator-=(POINT point);
void operator-=(SIZE size);
void operator-=(LPCRECT lpRect);
void operator&=(const RECT& rect);
void operator|=(const RECT& rect);
// Operators returning CRect values
CRect operator+(POINT point) const;
CRect operator-(POINT point) const;
CRect operator+(LPCRECT lpRect) const;
CRect operator+(SIZE size) const;
CRect operator-(SIZE size) const;
CRect operator-(LPCRECT lpRect) const;
CRect operator&(const RECT& rect2) const;
CRect operator|(const RECT& rect2) const;
CRect MulDiv(int nMultiplier, int nDivisor) const;
};
/////////////////////////////////////////////////////////////////////////////
// Strings
#ifndef _ATL_TMP_NO_CSTRING
#ifndef _OLEAUTO_H_
#ifdef OLE2ANSI
typedef LPSTR BSTR;
#else
typedef LPWSTR BSTR; // must (semantically) match typedef in oleauto.h
#endif
#endif
int __stdcall AfxLoadString(UINT nID, LPTSTR lpszBuf, UINT nMaxBuf);
struct CStringData
{
long nRefs; // reference count
int nDataLength;
int nAllocLength;
// TCHAR data[nAllocLength]
TCHAR* data()
{ return (TCHAR*)(this+1); }
};
class CString
{
public:
// Constructors
CString();
CString(const CString& stringSrc);
CString(TCHAR ch, int nRepeat = 1);
CString(LPCSTR lpsz);
CString(LPCWSTR lpsz);
CString(LPCTSTR lpch, int nLength);
CString(const unsigned char* psz);
// Attributes & Operations
// as an array of characters
int GetLength() const;
BOOL IsEmpty() const;
void Empty(); // free up the data
TCHAR GetAt(int nIndex) const; // 0 based
TCHAR operator[](int nIndex) const; // same as GetAt
void SetAt(int nIndex, TCHAR ch);
operator LPCTSTR() const; // as a C string
// overloaded assignment
const CString& operator=(const CString& stringSrc);
const CString& operator=(TCHAR ch);
#ifdef _UNICODE
const CString& operator=(char ch);
#endif
const CString& operator=(LPCSTR lpsz);
const CString& operator=(LPCWSTR lpsz);
const CString& operator=(const unsigned char* psz);
// string concatenation
const CString& operator+=(const CString& string);
const CString& operator+=(TCHAR ch);
#ifdef _UNICODE
const CString& operator+=(char ch);
#endif
const CString& operator+=(LPCTSTR lpsz);
friend CString __stdcall operator+(const CString& string1, const CString& string2);
friend CString __stdcall operator+(const CString& string, TCHAR ch);
friend CString __stdcall operator+(TCHAR ch, const CString& string);
#ifdef _UNICODE
friend CString __stdcall operator+(const CString& string, char ch);
friend CString __stdcall operator+(char ch, const CString& string);
#endif
friend CString __stdcall operator+(const CString& string, LPCTSTR lpsz);
friend CString __stdcall operator+(LPCTSTR lpsz, const CString& string);
// string comparison
int Compare(LPCTSTR lpsz) const; // straight character
int CompareNoCase(LPCTSTR lpsz) const; // ignore case
int Collate(LPCTSTR lpsz) const; // NLS aware
// simple sub-string extraction
CString Mid(int nFirst, int nCount) const;
CString Mid(int nFirst) const;
CString Left(int nCount) const;
CString Right(int nCount) const;
CString SpanIncluding(LPCTSTR lpszCharSet) const;
CString SpanExcluding(LPCTSTR lpszCharSet) const;
// upper/lower/reverse conversion
void MakeUpper();
void MakeLower();
void MakeReverse();
// trimming whitespace (either side)
void TrimRight();
void TrimLeft();
// searching (return starting index, or -1 if not found)
// look for a single character match
int Find(TCHAR ch) const; // like "C" strchr
int ReverseFind(TCHAR ch) const;
int FindOneOf(LPCTSTR lpszCharSet) const;
// look for a specific sub-string
int Find(LPCTSTR lpszSub) const; // like "C" strstr
// simple formatting
void __cdecl Format(LPCTSTR lpszFormat, ...);
void __cdecl Format(UINT nFormatID, ...);
// formatting for localization (uses FormatMessage API)
BOOL __cdecl FormatMessage(LPCTSTR lpszFormat, ...);
BOOL __cdecl FormatMessage(UINT nFormatID, ...);
// Windows support
BOOL LoadString(UINT nID); // load from string resource
// 255 chars max
#ifndef _UNICODE
// ANSI <-> OEM support (convert string in place)
void AnsiToOem();
void OemToAnsi();
#endif
#ifndef _ATL_NO_COM
// OLE BSTR support (use for OLE automation)
BSTR AllocSysString() const;
BSTR SetSysString(BSTR* pbstr) const;
#endif //!_ATL_NO_COM
// Access to string implementation buffer as "C" character array
LPTSTR GetBuffer(int nMinBufLength);
void ReleaseBuffer(int nNewLength = -1);
LPTSTR GetBufferSetLength(int nNewLength);
void FreeExtra();
// Use LockBuffer/UnlockBuffer to turn refcounting off
LPTSTR LockBuffer();
void UnlockBuffer();
// Implementation
public:
~CString();
int GetAllocLength() const;
protected:
LPTSTR m_pchData; // pointer to ref counted string data
// implementation helpers
CStringData* GetData() const;
void Init();
void AllocCopy(CString& dest, int nCopyLen, int nCopyIndex, int nExtraLen) const;
BOOL AllocBuffer(int nLen);
void AssignCopy(int nSrcLen, LPCTSTR lpszSrcData);
void ConcatCopy(int nSrc1Len, LPCTSTR lpszSrc1Data, int nSrc2Len, LPCTSTR lpszSrc2Data);
void ConcatInPlace(int nSrcLen, LPCTSTR lpszSrcData);
void FormatV(LPCTSTR lpszFormat, va_list argList);
void CopyBeforeWrite();
BOOL AllocBeforeWrite(int nLen);
void Release();
static void PASCAL Release(CStringData* pData);
static int PASCAL SafeStrlen(LPCTSTR lpsz);
};
// Compare helpers
bool __stdcall operator==(const CString& s1, const CString& s2);
bool __stdcall operator==(const CString& s1, LPCTSTR s2);
bool __stdcall operator==(LPCTSTR s1, const CString& s2);
bool __stdcall operator!=(const CString& s1, const CString& s2);
bool __stdcall operator!=(const CString& s1, LPCTSTR s2);
bool __stdcall operator!=(LPCTSTR s1, const CString& s2);
bool __stdcall operator<(const CString& s1, const CString& s2);
bool __stdcall operator<(const CString& s1, LPCTSTR s2);
bool __stdcall operator<(LPCTSTR s1, const CString& s2);
bool __stdcall operator>(const CString& s1, const CString& s2);
bool __stdcall operator>(const CString& s1, LPCTSTR s2);
bool __stdcall operator>(LPCTSTR s1, const CString& s2);
bool __stdcall operator<=(const CString& s1, const CString& s2);
bool __stdcall operator<=(const CString& s1, LPCTSTR s2);
bool __stdcall operator<=(LPCTSTR s1, const CString& s2);
bool __stdcall operator>=(const CString& s1, const CString& s2);
bool __stdcall operator>=(const CString& s1, LPCTSTR s2);
bool __stdcall operator>=(LPCTSTR s1, const CString& s2);
// conversion helpers
int __cdecl _wcstombsz(char* mbstr, const wchar_t* wcstr, size_t count);
int __cdecl _mbstowcsz(wchar_t* wcstr, const char* mbstr, size_t count);
// Globals
// afxChNil is left for backward compatibility
_declspec(selectany) 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)
_declspec(selectany) int rgInitData[] = { -1, 0, 0, 0 };
_declspec(selectany) CStringData* afxDataNil = (CStringData*)&rgInitData;
_declspec(selectany) LPCTSTR afxPchNil = (LPCTSTR)(((BYTE*)&rgInitData)+sizeof(CStringData));
inline const CString& __stdcall AfxGetEmptyString()
{ return *(CString*)&afxPchNil; }
#define afxEmptyString AfxGetEmptyString()
#endif //!_ATL_TMP_NO_CSTRING
/////////////////////////////////////////////////////////////////////////////
// Implementation
// CSize
inline CSize::CSize() {
cx = 0;
cy = 0;
}
inline CSize::CSize(int initCX, int initCY)
{ cx = initCX; cy = initCY; }
inline CSize::CSize(SIZE initSize)
{ *(SIZE*)this = initSize; }
inline CSize::CSize(POINT initPt)
{ *(POINT*)this = initPt; }
inline CSize::CSize(DWORD dwSize)
{
cx = (short)LOWORD(dwSize);
cy = (short)HIWORD(dwSize);
}
inline BOOL CSize::operator==(SIZE size) const
{ return (cx == size.cx && cy == size.cy); }
inline BOOL CSize::operator!=(SIZE size) const
{ return (cx != size.cx || cy != size.cy); }
inline void CSize::operator+=(SIZE size)
{ cx += size.cx; cy += size.cy; }
inline void CSize::operator-=(SIZE size)
{ cx -= size.cx; cy -= size.cy; }
inline CSize CSize::operator+(SIZE size) const
{ return CSize(cx + size.cx, cy + size.cy); }
inline CSize CSize::operator-(SIZE size) const
{ return CSize(cx - size.cx, cy - size.cy); }
inline CSize CSize::operator-() const
{ return CSize(-cx, -cy); }
inline CPoint CSize::operator+(POINT point) const
{ return CPoint(cx + point.x, cy + point.y); }
inline CPoint CSize::operator-(POINT point) const
{ return CPoint(cx - point.x, cy - point.y); }
inline CRect CSize::operator+(const RECT* lpRect) const
{ return CRect(lpRect) + *this; }
inline CRect CSize::operator-(const RECT* lpRect) const
{ return CRect(lpRect) - *this; }
// CPoint
inline CPoint::CPoint(int initX, int initY)
{ x = initX; y = initY; }
inline CPoint::CPoint(POINT initPt)
{ *(POINT*)this = initPt; }
inline CPoint::CPoint(SIZE initSize)
{ *(SIZE*)this = initSize; }
inline CPoint::CPoint(DWORD dwPoint)
{
x = (short)LOWORD(dwPoint);
y = (short)HIWORD(dwPoint);
}
inline void CPoint::Offset(int xOffset, int yOffset)
{ x += xOffset; y += yOffset; }
inline void CPoint::Offset(POINT point)
{ x += point.x; y += point.y; }
inline void CPoint::Offset(SIZE size)
{ x += size.cx; y += size.cy; }
inline BOOL CPoint::operator==(POINT point) const
{ return (x == point.x && y == point.y); }
inline BOOL CPoint::operator!=(POINT point) const
{ return (x != point.x || y != point.y); }
inline void CPoint::operator+=(SIZE size)
{ x += size.cx; y += size.cy; }
inline void CPoint::operator-=(SIZE size)
{ x -= size.cx; y -= size.cy; }
inline void CPoint::operator+=(POINT point)
{ x += point.x; y += point.y; }
inline void CPoint::operator-=(POINT point)
{ x -= point.x; y -= point.y; }
inline CPoint CPoint::operator+(SIZE size) const
{ return CPoint(x + size.cx, y + size.cy); }
inline CPoint CPoint::operator-(SIZE size) const
{ return CPoint(x - size.cx, y - size.cy); }
inline CPoint CPoint::operator-() const
{ return CPoint(-x, -y); }
inline CPoint CPoint::operator+(POINT point) const
{ return CPoint(x + point.x, y + point.y); }
inline CSize CPoint::operator-(POINT point) const
{ return CSize(x - point.x, y - point.y); }
inline CRect CPoint::operator+(const RECT* lpRect) const
{ return CRect(lpRect) + *this; }
inline CRect CPoint::operator-(const RECT* lpRect) const
{ return CRect(lpRect) - *this; }
// CRect
inline CRect::CRect(int l, int t, int r, int b)
{ left = l; top = t; right = r; bottom = b; }
inline CRect::CRect(const RECT& srcRect)
{ ::CopyRect(this, &srcRect); }
inline CRect::CRect(LPCRECT lpSrcRect)
{ ::CopyRect(this, lpSrcRect); }
inline CRect::CRect(POINT point, SIZE size)
{ right = (left = point.x) + size.cx; bottom = (top = point.y) + size.cy; }
inline CRect::CRect(POINT topLeft, POINT bottomRight)
{ left = topLeft.x; top = topLeft.y;
right = bottomRight.x; bottom = bottomRight.y; }
inline int CRect::Width() const
{ return right - left; }
inline int CRect::Height() const
{ return bottom - top; }
inline CSize CRect::Size() const
{ return CSize(right - left, bottom - top); }
inline CPoint& CRect::TopLeft()
{ return *((CPoint*)this); }
inline CPoint& CRect::BottomRight()
{ return *((CPoint*)this+1); }
inline const CPoint& CRect::TopLeft() const
{ return *((CPoint*)this); }
inline const CPoint& CRect::BottomRight() const
{ return *((CPoint*)this+1); }
inline CPoint CRect::CenterPoint() const
{ return CPoint((left+right)/2, (top+bottom)/2); }
inline CRect::operator LPRECT()
{ return this; }
inline CRect::operator LPCRECT() const
{ return this; }
inline BOOL CRect::IsRectEmpty() const
{ return ::IsRectEmpty(this); }
inline BOOL CRect::IsRectNull() const
{ return (left == 0 && right == 0 && top == 0 && bottom == 0); }
inline BOOL CRect::PtInRect(POINT point) const
{ return ::PtInRect(this, point); }
inline void CRect::SetRect(int x1, int y1, int x2, int y2)
{ ::SetRect(this, x1, y1, x2, y2); }
inline void CRect::SetRect(POINT topLeft, POINT bottomRight)
{ ::SetRect(this, topLeft.x, topLeft.y, bottomRight.x, bottomRight.y); }
inline void CRect::SetRectEmpty()
{ ::SetRectEmpty(this); }
inline void CRect::CopyRect(LPCRECT lpSrcRect)
{ ::CopyRect(this, lpSrcRect); }
inline BOOL CRect::EqualRect(LPCRECT lpRect) const
{ return ::EqualRect(this, lpRect); }
inline void CRect::InflateRect(int x, int y)
{ ::InflateRect(this, x, y); }
inline void CRect::InflateRect(SIZE size)
{ ::InflateRect(this, size.cx, size.cy); }
inline void CRect::DeflateRect(int x, int y)
{ ::InflateRect(this, -x, -y); }
inline void CRect::DeflateRect(SIZE size)
{ ::InflateRect(this, -size.cx, -size.cy); }
inline void CRect::OffsetRect(int x, int y)
{ ::OffsetRect(this, x, y); }
inline void CRect::OffsetRect(POINT point)
{ ::OffsetRect(this, point.x, point.y); }
inline void CRect::OffsetRect(SIZE size)
{ ::OffsetRect(this, size.cx, size.cy); }
inline BOOL CRect::IntersectRect(LPCRECT lpRect1, LPCRECT lpRect2)
{ return ::IntersectRect(this, lpRect1, lpRect2);}
inline BOOL CRect::IntersectRect(LPCRECT lpRect2)
{ return ::IntersectRect(this, this, lpRect2);}
inline BOOL CRect::UnionRect(LPCRECT lpRect1, LPCRECT lpRect2)
{ return ::UnionRect(this, lpRect1, lpRect2); }
inline void CRect::operator=(const RECT& srcRect)
{ ::CopyRect(this, &srcRect); }
inline BOOL CRect::operator==(const RECT& rect) const
{ return ::EqualRect(this, &rect); }
inline BOOL CRect::operator!=(const RECT& rect) const
{ return !::EqualRect(this, &rect); }
inline void CRect::operator+=(POINT point)
{ ::OffsetRect(this, point.x, point.y); }
inline void CRect::operator+=(SIZE size)
{ ::OffsetRect(this, size.cx, size.cy); }
inline void CRect::operator+=(LPCRECT lpRect)
{ InflateRect(lpRect); }
inline void CRect::operator-=(POINT point)
{ ::OffsetRect(this, -point.x, -point.y); }
inline void CRect::operator-=(SIZE size)
{ ::OffsetRect(this, -size.cx, -size.cy); }
inline void CRect::operator-=(LPCRECT lpRect)
{ DeflateRect(lpRect); }
inline void CRect::operator&=(const RECT& rect)
{ ::IntersectRect(this, this, &rect); }
inline void CRect::operator|=(const RECT& rect)
{ ::UnionRect(this, this, &rect); }
inline CRect CRect::operator+(POINT pt) const
{ CRect rect(*this); ::OffsetRect(&rect, pt.x, pt.y); return rect; }
inline CRect CRect::operator-(POINT pt) const
{ CRect rect(*this); ::OffsetRect(&rect, -pt.x, -pt.y); return rect; }
inline CRect CRect::operator+(SIZE size) const
{ CRect rect(*this); ::OffsetRect(&rect, size.cx, size.cy); return rect; }
inline CRect CRect::operator-(SIZE size) const
{ CRect rect(*this); ::OffsetRect(&rect, -size.cx, -size.cy); return rect; }
inline CRect CRect::operator+(LPCRECT lpRect) const
{ CRect rect(this); rect.InflateRect(lpRect); return rect; }
inline CRect CRect::operator-(LPCRECT lpRect) const
{ CRect rect(this); rect.DeflateRect(lpRect); return rect; }
inline CRect CRect::operator&(const RECT& rect2) const
{ CRect rect; ::IntersectRect(&rect, this, &rect2);
return rect; }
inline CRect CRect::operator|(const RECT& rect2) const
{ CRect rect; ::UnionRect(&rect, this, &rect2);
return rect; }
inline BOOL CRect::SubtractRect(LPCRECT lpRectSrc1, LPCRECT lpRectSrc2)
{ return ::SubtractRect(this, lpRectSrc1, lpRectSrc2); }
inline void CRect::NormalizeRect()
{
int nTemp;
if (left > right)
{
nTemp = left;
left = right;
right = nTemp;
}
if (top > bottom)
{
nTemp = top;
top = bottom;
bottom = nTemp;
}
}
inline void CRect::InflateRect(LPCRECT lpRect)
{
left -= lpRect->left;
top -= lpRect->top;
right += lpRect->right;
bottom += lpRect->bottom;
}
inline void CRect::InflateRect(int l, int t, int r, int b)
{
left -= l;
top -= t;
right += r;
bottom += b;
}
inline void CRect::DeflateRect(LPCRECT lpRect)
{
left += lpRect->left;
top += lpRect->top;
right -= lpRect->right;
bottom -= lpRect->bottom;
}
inline void CRect::DeflateRect(int l, int t, int r, int b)
{
left += l;
top += t;
right -= r;
bottom -= b;
}
inline CRect CRect::MulDiv(int nMultiplier, int nDivisor) const
{
return CRect(
::MulDiv(left, nMultiplier, nDivisor),
::MulDiv(top, nMultiplier, nDivisor),
::MulDiv(right, nMultiplier, nDivisor),
::MulDiv(bottom, nMultiplier, nDivisor));
}
#ifndef _ATL_TMP_NO_CSTRING
// CString
inline CStringData* CString::GetData() const
{ ATLASSERT(m_pchData != NULL); return ((CStringData*)m_pchData)-1; }
inline void CString::Init()
{ m_pchData = afxEmptyString.m_pchData; }
inline CString::CString(const unsigned char* lpsz)
{ Init(); *this = (LPCSTR)lpsz; }
inline const CString& CString::operator=(const unsigned char* lpsz)
{ *this = (LPCSTR)lpsz; return *this; }
#ifdef _UNICODE
inline const CString& CString::operator+=(char ch)
{ *this += (TCHAR)ch; return *this; }
inline const CString& CString::operator=(char ch)
{ *this = (TCHAR)ch; return *this; }
inline CString __stdcall operator+(const CString& string, char ch)
{ return string + (TCHAR)ch; }
inline CString __stdcall operator+(char ch, const CString& string)
{ return (TCHAR)ch + string; }
#endif
inline int CString::GetLength() const
{ return GetData()->nDataLength; }
inline int CString::GetAllocLength() const
{ return GetData()->nAllocLength; }
inline BOOL CString::IsEmpty() const
{ return GetData()->nDataLength == 0; }
inline CString::operator LPCTSTR() const
{ return m_pchData; }
inline int PASCAL CString::SafeStrlen(LPCTSTR lpsz)
{ return (lpsz == NULL) ? 0 : lstrlen(lpsz); }
// CString support (windows specific)
inline int CString::Compare(LPCTSTR lpsz) const
{ return _tcscmp(m_pchData, lpsz); } // MBCS/Unicode aware
inline int CString::CompareNoCase(LPCTSTR lpsz) const
{ return _tcsicmp(m_pchData, lpsz); } // MBCS/Unicode aware
// CString::Collate is often slower than Compare but is MBSC/Unicode
// aware as well as locale-sensitive with respect to sort order.
inline int CString::Collate(LPCTSTR lpsz) const
{ return _tcscoll(m_pchData, lpsz); } // locale sensitive
inline TCHAR CString::GetAt(int nIndex) const
{
ATLASSERT(nIndex >= 0);
ATLASSERT(nIndex < GetData()->nDataLength);
return m_pchData[nIndex];
}
inline TCHAR CString::operator[](int nIndex) const
{
// same as GetAt
ATLASSERT(nIndex >= 0);
ATLASSERT(nIndex < GetData()->nDataLength);
return m_pchData[nIndex];
}
inline bool __stdcall operator==(const CString& s1, const CString& s2)
{ return s1.Compare(s2) == 0; }
inline bool __stdcall operator==(const CString& s1, LPCTSTR s2)
{ return s1.Compare(s2) == 0; }
inline bool __stdcall operator==(LPCTSTR s1, const CString& s2)
{ return s2.Compare(s1) == 0; }
inline bool __stdcall operator!=(const CString& s1, const CString& s2)
{ return s1.Compare(s2) != 0; }
inline bool __stdcall operator!=(const CString& s1, LPCTSTR s2)
{ return s1.Compare(s2) != 0; }
inline bool __stdcall operator!=(LPCTSTR s1, const CString& s2)
{ return s2.Compare(s1) != 0; }
inline bool __stdcall operator<(const CString& s1, const CString& s2)
{ return s1.Compare(s2) < 0; }
inline bool __stdcall operator<(const CString& s1, LPCTSTR s2)
{ return s1.Compare(s2) < 0; }
inline bool __stdcall operator<(LPCTSTR s1, const CString& s2)
{ return s2.Compare(s1) > 0; }
inline bool __stdcall operator>(const CString& s1, const CString& s2)
{ return s1.Compare(s2) > 0; }
inline bool __stdcall operator>(const CString& s1, LPCTSTR s2)
{ return s1.Compare(s2) > 0; }
inline bool __stdcall operator>(LPCTSTR s1, const CString& s2)
{ return s2.Compare(s1) < 0; }
inline bool __stdcall operator<=(const CString& s1, const CString& s2)
{ return s1.Compare(s2) <= 0; }
inline bool __stdcall operator<=(const CString& s1, LPCTSTR s2)
{ return s1.Compare(s2) <= 0; }
inline bool __stdcall operator<=(LPCTSTR s1, const CString& s2)
{ return s2.Compare(s1) >= 0; }
inline bool __stdcall operator>=(const CString& s1, const CString& s2)
{ return s1.Compare(s2) >= 0; }
inline bool __stdcall operator>=(const CString& s1, LPCTSTR s2)
{ return s1.Compare(s2) >= 0; }
inline bool __stdcall operator>=(LPCTSTR s1, const CString& s2)
{ return s2.Compare(s1) <= 0; }
inline BOOL __stdcall AfxIsValidString(LPCWSTR lpsz, int nLength)
{
if(lpsz == NULL)
return FALSE;
return !::IsBadStringPtrW(lpsz, nLength);
}
inline BOOL __stdcall AfxIsValidString(LPCSTR lpsz, int nLength)
{
if(lpsz == NULL)
return FALSE;
return !::IsBadStringPtrA(lpsz, nLength);
}
inline BOOL __stdcall AfxIsValidAddress(const void* lp, UINT nBytes, BOOL bReadWrite = TRUE)
{
// simple version using Win-32 APIs for pointer validation.
return (lp != NULL && !IsBadReadPtr(lp, nBytes) &&
(!bReadWrite || !IsBadWritePtr((LPVOID)lp, nBytes)));
}
inline CString::CString()
{
Init();
}
inline CString::CString(const CString& stringSrc)
{
ATLASSERT(stringSrc.GetData()->nRefs != 0);
if (stringSrc.GetData()->nRefs >= 0)
{
ATLASSERT(stringSrc.GetData() != afxDataNil);
m_pchData = stringSrc.m_pchData;
InterlockedIncrement(&GetData()->nRefs);
}
else
{
Init();
*this = stringSrc.m_pchData;
}
}
inline BOOL CString::AllocBuffer(int nLen)
// always allocate one extra character for '\0' termination
// assumes [optimistically] that data length will equal allocation length
{
ATLASSERT(nLen >= 0);
ATLASSERT(nLen <= INT_MAX-1); // max size (enough room for 1 extra)
if (nLen == 0)
Init();
else
{
CStringData* pData = NULL;
ATLTRY(pData = (CStringData*)new BYTE[sizeof(CStringData) + (nLen+1)*sizeof(TCHAR)]);
if(pData == NULL)
return FALSE;
pData->nRefs = 1;
pData->data()[nLen] = '\0';
pData->nDataLength = nLen;
pData->nAllocLength = nLen;
m_pchData = pData->data();
}
return TRUE;
}
inline void CString::Release()
{
if (GetData() != afxDataNil)
{
ATLASSERT(GetData()->nRefs != 0);
if (InterlockedDecrement(&GetData()->nRefs) <= 0)
delete[] (BYTE*)GetData();
Init();
}
}
inline void PASCAL CString::Release(CStringData* pData)
{
if (pData != afxDataNil)
{
ATLASSERT(pData->nRefs != 0);
if (InterlockedDecrement(&pData->nRefs) <= 0)
delete[] (BYTE*)pData;
}
}
inline void CString::Empty()
{
if (GetData()->nDataLength == 0)
return;
if (GetData()->nRefs >= 0)
Release();
else
*this = &afxChNil;
ATLASSERT(GetData()->nDataLength == 0);
ATLASSERT(GetData()->nRefs < 0 || GetData()->nAllocLength == 0);
}
inline void CString::CopyBeforeWrite()
{
if (GetData()->nRefs > 1)
{
CStringData* pData = GetData();
Release();
if(AllocBuffer(pData->nDataLength))
memcpy(m_pchData, pData->data(), (pData->nDataLength+1)*sizeof(TCHAR));
}
ATLASSERT(GetData()->nRefs <= 1);
}
inline BOOL CString::AllocBeforeWrite(int nLen)
{
BOOL bRet = TRUE;
if (GetData()->nRefs > 1 || nLen > GetData()->nAllocLength)
{
Release();
bRet = AllocBuffer(nLen);
}
ATLASSERT(GetData()->nRefs <= 1);
return bRet;
}
inline CString::~CString()
// free any attached data
{
if (GetData() != afxDataNil)
{
if (InterlockedDecrement(&GetData()->nRefs) <= 0)
delete[] (BYTE*)GetData();
}
}
inline 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
{
if(dest.AllocBuffer(nNewLen))
memcpy(dest.m_pchData, m_pchData+nCopyIndex, nCopyLen*sizeof(TCHAR));
}
}
inline CString::CString(LPCTSTR lpsz)
{
Init();
if (lpsz != NULL && HIWORD(lpsz) == NULL)
{
UINT nID = LOWORD((DWORD_PTR)lpsz);
if (!LoadString(nID))
#if (_ATL_VER >= 0x0300)
ATLTRACE2(atlTraceGeneral, 0, _T("Warning: implicit LoadString(%u) in CString failed\n"), nID);
#else
ATLTRACE2(atlTraceGeneral, 0, _T("Warning: implicit LoadString in CString failed\n"));
#endif //(_ATL_VER >= 0x0300)
}
else
{
int nLen = SafeStrlen(lpsz);
if (nLen != 0)
{
if(AllocBuffer(nLen))
memcpy(m_pchData, lpsz, nLen*sizeof(TCHAR));
}
}
}
#ifdef _UNICODE
inline CString::CString(LPCSTR lpsz)
{
Init();
int nSrcLen = lpsz != NULL ? lstrlenA(lpsz) : 0;
if (nSrcLen != 0)
{
if(AllocBuffer(nSrcLen))
{
_mbstowcsz(m_pchData, lpsz, nSrcLen+1);
ReleaseBuffer();
}
}
}
#else //_UNICODE
inline CString::CString(LPCWSTR lpsz)
{
Init();
int nSrcLen = lpsz != NULL ? wcslen(lpsz) : 0;
if (nSrcLen != 0)
{
if(AllocBuffer(nSrcLen*2))
{
_wcstombsz(m_pchData, lpsz, (nSrcLen*2)+1);
ReleaseBuffer();
}
}
}
#endif //!_UNICODE
// 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".
//
inline void CString::AssignCopy(int nSrcLen, LPCTSTR lpszSrcData)
{
if(AllocBeforeWrite(nSrcLen))
{
memcpy(m_pchData, lpszSrcData, nSrcLen*sizeof(TCHAR));
GetData()->nDataLength = nSrcLen;
m_pchData[nSrcLen] = '\0';
}
}
inline 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();
ATLASSERT(stringSrc.GetData() != afxDataNil);
m_pchData = stringSrc.m_pchData;
InterlockedIncrement(&GetData()->nRefs);
}
}
return *this;
}
inline const CString& CString::operator=(LPCTSTR lpsz)
{
ATLASSERT(lpsz == NULL || AfxIsValidString(lpsz, FALSE));
AssignCopy(SafeStrlen(lpsz), lpsz);
return *this;
}
#ifdef _UNICODE
inline const CString& CString::operator=(LPCSTR lpsz)
{
int nSrcLen = lpsz != NULL ? lstrlenA(lpsz) : 0;
if(AllocBeforeWrite(nSrcLen))
{
_mbstowcsz(m_pchData, lpsz, nSrcLen+1);
ReleaseBuffer();
}
return *this;
}
#else //!_UNICODE
inline const CString& CString::operator=(LPCWSTR lpsz)
{
int nSrcLen = lpsz != NULL ? wcslen(lpsz) : 0;
if(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
inline 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)
{
if(AllocBuffer(nNewLen))
{
memcpy(m_pchData, lpszSrc1Data, nSrc1Len*sizeof(TCHAR));
memcpy(m_pchData+nSrc1Len, lpszSrc2Data, nSrc2Len*sizeof(TCHAR));
}
}
}
inline CString __stdcall 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;
}
inline CString __stdcall operator+(const CString& string, LPCTSTR lpsz)
{
ATLASSERT(lpsz == NULL || AfxIsValidString(lpsz, FALSE));
CString s;
s.ConcatCopy(string.GetData()->nDataLength, string.m_pchData,
CString::SafeStrlen(lpsz), lpsz);
return s;
}
inline CString __stdcall operator+(LPCTSTR lpsz, const CString& string)
{
ATLASSERT(lpsz == NULL || AfxIsValidString(lpsz, FALSE));
CString s;
s.ConcatCopy(CString::SafeStrlen(lpsz), lpsz, string.GetData()->nDataLength,
string.m_pchData);
return s;
}
inline void CString::ConcatInPlace(int nSrcLen, LPCTSTR lpszSrcData)
{
// -- the main routine for += operators
// concatenating an empty string is a no-op!
if (nSrcLen == 0)
return;
// 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);
ATLASSERT(pOldData != NULL);
CString::Release(pOldData);
}
else
{
// fast concatenation when buffer big enough
memcpy(m_pchData+GetData()->nDataLength, lpszSrcData, nSrcLen*sizeof(TCHAR));
GetData()->nDataLength += nSrcLen;
ATLASSERT(GetData()->nDataLength <= GetData()->nAllocLength);
m_pchData[GetData()->nDataLength] = '\0';
}
}
inline const CString& CString::operator+=(LPCTSTR lpsz)
{
ATLASSERT(lpsz == NULL || AfxIsValidString(lpsz, FALSE));
ConcatInPlace(SafeStrlen(lpsz), lpsz);
return *this;
}
inline const CString& CString::operator+=(TCHAR ch)
{
ConcatInPlace(1, &ch);
return *this;
}
inline const CString& CString::operator+=(const CString& string)
{
ConcatInPlace(string.GetData()->nDataLength, string.m_pchData);
return *this;
}
inline LPTSTR CString::GetBuffer(int nMinBufLength)
{
ATLASSERT(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;
if(AllocBuffer(nMinBufLength))
{
memcpy(m_pchData, pOldData->data(), (nOldLen+1)*sizeof(TCHAR));
GetData()->nDataLength = nOldLen;
CString::Release(pOldData);
}
}
ATLASSERT(GetData()->nRefs <= 1);
// return a pointer to the character storage for this string
ATLASSERT(m_pchData != NULL);
return m_pchData;
}
inline void CString::ReleaseBuffer(int nNewLength)
{
CopyBeforeWrite(); // just in case GetBuffer was not called
if (nNewLength == -1)
nNewLength = lstrlen(m_pchData); // zero terminated
ATLASSERT(nNewLength <= GetData()->nAllocLength);
GetData()->nDataLength = nNewLength;
m_pchData[nNewLength] = '\0';
}
inline LPTSTR CString::GetBufferSetLength(int nNewLength)
{
ATLASSERT(nNewLength >= 0);
GetBuffer(nNewLength);
GetData()->nDataLength = nNewLength;
m_pchData[nNewLength] = '\0';
return m_pchData;
}
inline void CString::FreeExtra()
{
ATLASSERT(GetData()->nDataLength <= GetData()->nAllocLength);
if (GetData()->nDataLength != GetData()->nAllocLength)
{
CStringData* pOldData = GetData();
if(AllocBuffer(GetData()->nDataLength))
{
memcpy(m_pchData, pOldData->data(), pOldData->nDataLength*sizeof(TCHAR));
ATLASSERT(m_pchData[GetData()->nDataLength] == '\0');
CString::Release(pOldData);
}
}
ATLASSERT(GetData() != NULL);
}
inline LPTSTR CString::LockBuffer()
{
LPTSTR lpsz = GetBuffer(0);
GetData()->nRefs = -1;
return lpsz;
}
inline void CString::UnlockBuffer()
{
ATLASSERT(GetData()->nRefs == -1);
if (GetData() != afxDataNil)
GetData()->nRefs = 1;
}
inline int CString::Find(TCHAR ch) const
{
// find first single character
LPTSTR lpsz = _tcschr(m_pchData, (_TUCHAR)ch);
// return -1 if not found and index otherwise
return (lpsz == NULL) ? -1 : (int)(lpsz - m_pchData);
}
inline int CString::FindOneOf(LPCTSTR lpszCharSet) const
{
ATLASSERT(AfxIsValidString(lpszCharSet, FALSE));
LPTSTR lpsz = _tcspbrk(m_pchData, lpszCharSet);
return (lpsz == NULL) ? -1 : (int)(lpsz - m_pchData);
}
inline void CString::MakeUpper()
{
CopyBeforeWrite();
_tcsupr(m_pchData);
}
inline void CString::MakeLower()
{
CopyBeforeWrite();
_tcslwr(m_pchData);
}
inline void CString::MakeReverse()
{
CopyBeforeWrite();
_tcsrev(m_pchData);
}
inline void CString::SetAt(int nIndex, TCHAR ch)
{
ATLASSERT(nIndex >= 0);
ATLASSERT(nIndex < GetData()->nDataLength);
CopyBeforeWrite();
m_pchData[nIndex] = ch;
}
#ifndef _UNICODE
inline void CString::AnsiToOem()
{
CopyBeforeWrite();
::AnsiToOem(m_pchData, m_pchData);
}
inline void CString::OemToAnsi()
{
CopyBeforeWrite();
::OemToAnsi(m_pchData, m_pchData);
}
#endif
// CString conversion helpers (these use the current system locale)
inline int __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);
ATLASSERT(mbstr == NULL || result <= (int)count);
if (result > 0)
mbstr[result-1] = 0;
return result;
}
inline int __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);
ATLASSERT(wcstr == NULL || result <= (int)count);
if (result > 0)
wcstr[result-1] = 0;
return result;
}
inline CString::CString(TCHAR ch, int nLength)
{
ATLASSERT(!_istlead(ch)); // can't create a lead byte string
Init();
if (nLength >= 1)
{
if(AllocBuffer(nLength))
{
#ifdef _UNICODE
for (int i = 0; i < nLength; i++)
m_pchData[i] = ch;
#else
memset(m_pchData, ch, nLength);
#endif
}
}
}
inline CString::CString(LPCTSTR lpch, int nLength)
{
Init();
if (nLength != 0)
{
ATLASSERT(AfxIsValidAddress(lpch, nLength, FALSE));
if(AllocBuffer(nLength))
memcpy(m_pchData, lpch, nLength*sizeof(TCHAR));
}
}
inline const CString& CString::operator=(TCHAR ch)
{
ATLASSERT(!_istlead(ch)); // can't set single lead byte
AssignCopy(1, &ch);
return *this;
}
inline CString __stdcall operator+(const CString& string1, TCHAR ch)
{
CString s;
s.ConcatCopy(string1.GetData()->nDataLength, string1.m_pchData, 1, &ch);
return s;
}
inline CString __stdcall operator+(TCHAR ch, const CString& string)
{
CString s;
s.ConcatCopy(1, &ch, string.GetData()->nDataLength, string.m_pchData);
return s;
}
inline CString CString::Mid(int nFirst) const
{
return Mid(nFirst, GetData()->nDataLength - nFirst);
}
inline 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;
}
inline CString CString::Right(int nCount) const
{
if (nCount < 0)
nCount = 0;
else if (nCount > GetData()->nDataLength)
nCount = GetData()->nDataLength;
CString dest;
AllocCopy(dest, nCount, GetData()->nDataLength-nCount, 0);
return dest;
}
inline 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;
}
// strspn equivalent
inline CString CString::SpanIncluding(LPCTSTR lpszCharSet) const
{
ATLASSERT(AfxIsValidString(lpszCharSet, FALSE));
return Left(_tcsspn(m_pchData, lpszCharSet));
}
// strcspn equivalent
inline CString CString::SpanExcluding(LPCTSTR lpszCharSet) const
{
ATLASSERT(AfxIsValidString(lpszCharSet, FALSE));
return Left(_tcscspn(m_pchData, lpszCharSet));
}
inline int CString::ReverseFind(TCHAR ch) const
{
// find last single character
LPTSTR lpsz = _tcsrchr(m_pchData, (_TUCHAR)ch);
// return -1 if not found, distance from beginning otherwise
return (lpsz == NULL) ? -1 : (int)(lpsz - m_pchData);
}
// find a sub-string (like strstr)
inline int CString::Find(LPCTSTR lpszSub) const
{
ATLASSERT(AfxIsValidString(lpszSub, FALSE));
// find first matching substring
LPTSTR lpsz = _tcsstr(m_pchData, lpszSub);
// return -1 for not found, distance from beginning otherwise
return (lpsz == NULL) ? -1 : (int)(lpsz - m_pchData);
}
#define TCHAR_ARG TCHAR
#define WCHAR_ARG WCHAR
#define CHAR_ARG char
struct _AFX_DOUBLE { BYTE doubleBits[sizeof(double)]; };
#if defined(_X86_)
#define DOUBLE_ARG _AFX_DOUBLE
#else
#define DOUBLE_ARG double
#endif
#define FORCE_ANSI 0x10000
#define FORCE_UNICODE 0x20000
inline void CString::FormatV(LPCTSTR lpszFormat, va_list argList)
{
ATLASSERT(AfxIsValidString(lpszFormat, FALSE));
va_list argListSave = argList;
// make a guess at the maximum length of the resulting string
int nMaxLen = 0;
for (LPCTSTR lpsz = lpszFormat; *lpsz != '\0'; lpsz = _tcsinc(lpsz))
{
// handle '%' character, but watch out for '%%'
if (*lpsz != '%' || *(lpsz = _tcsinc(lpsz)) == '%')
{
nMaxLen += _tclen(lpsz);
continue;
}
int nItemLen = 0;
// handle '%' character with format
int nWidth = 0;
for (; *lpsz != '\0'; lpsz = _tcsinc(lpsz))
{
// check for valid flags
if (*lpsz == '#')
nMaxLen += 2; // for '0x'
else if (*lpsz == '*')
nWidth = va_arg(argList, int);
else if (*lpsz == '-' || *lpsz == '+' || *lpsz == '0' ||
*lpsz == ' ')
;
else // hit non-flag character
break;
}
// get width and skip it
if (nWidth == 0)
{
// width indicated by
nWidth = _ttoi(lpsz);
for (; *lpsz != '\0' && _istdigit(*lpsz); lpsz = _tcsinc(lpsz))
;
}
ATLASSERT(nWidth >= 0);
int nPrecision = 0;
if (*lpsz == '.')
{
// skip past '.' separator (width.precision)
lpsz = _tcsinc(lpsz);
// get precision and skip it
if (*lpsz == '*')
{
nPrecision = va_arg(argList, int);
lpsz = _tcsinc(lpsz);
}
else
{
nPrecision = _ttoi(lpsz);
for (; *lpsz != '\0' && _istdigit(*lpsz); lpsz = _tcsinc(lpsz))
;
}
ATLASSERT(nPrecision >= 0);
}
// should be on type modifier or specifier
int nModifier = 0;
switch (*lpsz)
{
// modifiers that affect size
case 'h':
nModifier = FORCE_ANSI;
lpsz = _tcsinc(lpsz);
break;
case 'l':
nModifier = FORCE_UNICODE;
lpsz = _tcsinc(lpsz);
break;
// modifiers that do not affect size
case 'F':
case 'N':
case 'L':
lpsz = _tcsinc(lpsz);
break;
}
// now should be on specifier
switch (*lpsz | nModifier)
{
// single characters
case 'c':
case 'C':
nItemLen = 2;
va_arg(argList, TCHAR_ARG);
break;
case 'c'|FORCE_ANSI:
case 'C'|FORCE_ANSI:
nItemLen = 2;
va_arg(argList, CHAR_ARG);
break;
case 'c'|FORCE_UNICODE:
case 'C'|FORCE_UNICODE:
nItemLen = 2;
va_arg(argList, WCHAR_ARG);
break;
// strings
case 's':
{
LPCTSTR pstrNextArg = va_arg(argList, LPCTSTR);
if (pstrNextArg == NULL)
nItemLen = 6; // "(null)"
else
{
nItemLen = lstrlen(pstrNextArg);
nItemLen = max(1, nItemLen);
}
break;
}
case 'S':
{
#ifndef _UNICODE
LPWSTR pstrNextArg = va_arg(argList, LPWSTR);
if (pstrNextArg == NULL)
nItemLen = 6; // "(null)"
else
{
nItemLen = wcslen(pstrNextArg);
nItemLen = max(1, nItemLen);
}
#else
LPCSTR pstrNextArg = va_arg(argList, LPCSTR);
if (pstrNextArg == NULL)
nItemLen = 6; // "(null)"
else
{
nItemLen = lstrlenA(pstrNextArg);
nItemLen = max(1, nItemLen);
}
#endif
break;
}
case 's'|FORCE_ANSI:
case 'S'|FORCE_ANSI:
{
LPCSTR pstrNextArg = va_arg(argList, LPCSTR);
if (pstrNextArg == NULL)
nItemLen = 6; // "(null)"
else
{
nItemLen = lstrlenA(pstrNextArg);
nItemLen = max(1, nItemLen);
}
break;
}
case 's'|FORCE_UNICODE:
case 'S'|FORCE_UNICODE:
{
LPWSTR pstrNextArg = va_arg(argList, LPWSTR);
if (pstrNextArg == NULL)
nItemLen = 6; // "(null)"
else
{
nItemLen = wcslen(pstrNextArg);
nItemLen = max(1, nItemLen);
}
break;
}
}
// adjust nItemLen for strings
if (nItemLen != 0)
{
nItemLen = max(nItemLen, nWidth);
if (nPrecision != 0)
nItemLen = min(nItemLen, nPrecision);
}
else
{
switch (*lpsz)
{
// integers
case 'd':
case 'i':
case 'u':
case 'x':
case 'X':
case 'o':
va_arg(argList, int);
nItemLen = 32;
nItemLen = max(nItemLen, nWidth+nPrecision);
break;
case 'e':
case 'f':
case 'g':
case 'G':
va_arg(argList, DOUBLE_ARG);
nItemLen = 128;
nItemLen = max(nItemLen, nWidth+nPrecision);
break;
case 'p':
va_arg(argList, void*);
nItemLen = 32;
nItemLen = max(nItemLen, nWidth+nPrecision);
break;
// no output
case 'n':
va_arg(argList, int*);
break;
default:
ATLASSERT(FALSE); // unknown formatting option
}
}
// adjust nMaxLen for output nItemLen
nMaxLen += nItemLen;
}
GetBuffer(nMaxLen);
int nRet = _vstprintf(m_pchData, lpszFormat, argListSave);
nRet; // ref
ATLASSERT(nRet <= GetAllocLength());
ReleaseBuffer();
va_end(argListSave);
}
// formatting (using wsprintf style formatting)
inline void __cdecl CString::Format(LPCTSTR lpszFormat, ...)
{
ATLASSERT(AfxIsValidString(lpszFormat, FALSE));
va_list argList;
va_start(argList, lpszFormat);
FormatV(lpszFormat, argList);
va_end(argList);
}
inline void __cdecl CString::Format(UINT nFormatID, ...)
{
CString strFormat;
BOOL bRet = strFormat.LoadString(nFormatID);
bRet; // ref
ATLASSERT(bRet != 0);
va_list argList;
va_start(argList, nFormatID);
FormatV(strFormat, argList);
va_end(argList);
}
// formatting (using FormatMessage style formatting)
inline BOOL __cdecl CString::FormatMessage(LPCTSTR lpszFormat, ...)
{
// format message into temporary buffer lpszTemp
va_list argList;
va_start(argList, lpszFormat);
LPTSTR lpszTemp;
BOOL bRet = TRUE;
if (::FormatMessage(FORMAT_MESSAGE_FROM_STRING|FORMAT_MESSAGE_ALLOCATE_BUFFER,
lpszFormat, 0, 0, (LPTSTR)&lpszTemp, 0, &argList) == 0 ||
lpszTemp == NULL)
bRet = FALSE;
// assign lpszTemp into the resulting string and free the temporary
*this = lpszTemp;
LocalFree(lpszTemp);
va_end(argList);
return bRet;
}
inline BOOL __cdecl CString::FormatMessage(UINT nFormatID, ...)
{
// get format string from string table
CString strFormat;
BOOL bRetTmp = strFormat.LoadString(nFormatID);
bRetTmp; // ref
ATLASSERT(bRetTmp != 0);
// format message into temporary buffer lpszTemp
va_list argList;
va_start(argList, nFormatID);
LPTSTR lpszTemp;
BOOL bRet = TRUE;
if (::FormatMessage(FORMAT_MESSAGE_FROM_STRING|FORMAT_MESSAGE_ALLOCATE_BUFFER,
strFormat, 0, 0, (LPTSTR)&lpszTemp, 0, &argList) == 0 ||
lpszTemp == NULL)
bRet = FALSE;
// assign lpszTemp into the resulting string and free lpszTemp
*this = lpszTemp;
LocalFree(lpszTemp);
va_end(argList);
return bRet;
}
inline void CString::TrimRight()
{
CopyBeforeWrite();
// find beginning of trailing spaces by starting at beginning (DBCS aware)
LPTSTR lpsz = m_pchData;
LPTSTR lpszLast = NULL;
while (*lpsz != '\0')
{
if (_istspace(*lpsz))
{
if (lpszLast == NULL)
lpszLast = lpsz;
}
else
lpszLast = NULL;
lpsz = _tcsinc(lpsz);
}
if (lpszLast != NULL)
{
// truncate at trailing space start
*lpszLast = '\0';
GetData()->nDataLength = (int)(DWORD_PTR)(lpszLast - m_pchData);
}
}
inline void CString::TrimLeft()
{
CopyBeforeWrite();
// find first non-space character
LPCTSTR lpsz = m_pchData;
while (_istspace(*lpsz))
lpsz = _tcsinc(lpsz);
// fix up data and length
int nDataLength = GetData()->nDataLength - (int)(DWORD_PTR)(lpsz - m_pchData);
memmove(m_pchData, lpsz, (nDataLength+1)*sizeof(TCHAR));
GetData()->nDataLength = nDataLength;
}
#ifdef _UNICODE
#define CHAR_FUDGE 1 // one TCHAR unused is good enough
#else
#define CHAR_FUDGE 2 // two BYTES unused for case of DBC last char
#endif
inline BOOL CString::LoadString(UINT nID)
{
// try fixed buffer first (to avoid wasting space in the heap)
TCHAR szTemp[256];
int nCount = sizeof(szTemp) / sizeof(szTemp[0]);
int nLen = AfxLoadString(nID, szTemp, nCount);
if (nCount - nLen > CHAR_FUDGE)
{
*this = szTemp;
return nLen > 0;
}
// try buffer size of 512, then larger size until entire string is retrieved
int nSize = 256;
do
{
nSize += 256;
nLen = AfxLoadString(nID, GetBuffer(nSize-1), nSize);
} while (nSize - nLen <= CHAR_FUDGE);
ReleaseBuffer();
return nLen > 0;
}
inline int __stdcall AfxLoadString(UINT nID, LPTSTR lpszBuf, UINT nMaxBuf)
{
ATLASSERT(AfxIsValidAddress(lpszBuf, nMaxBuf*sizeof(TCHAR)));
#ifdef _DEBUG
// LoadString without annoying warning from the Debug kernel if the
// segment containing the string is not present
if (::FindResource(_Module.GetResourceInstance(),
MAKEINTRESOURCE((nID>>4)+1), RT_STRING) == NULL)
{
lpszBuf[0] = '\0';
return 0; // not found
}
#endif //_DEBUG
int nLen = ::LoadString(_Module.GetResourceInstance(), nID, lpszBuf, nMaxBuf);
if (nLen == 0)
lpszBuf[0] = '\0';
return nLen;
}
#ifndef _ATL_NO_COM
inline BSTR CString::AllocSysString() const
{
#if defined(_UNICODE) || defined(OLE2ANSI)
BSTR bstr = ::SysAllocStringLen(m_pchData, GetData()->nDataLength);
#else
int nLen = MultiByteToWideChar(CP_ACP, 0, m_pchData,
GetData()->nDataLength, NULL, NULL);
BSTR bstr = ::SysAllocStringLen(NULL, nLen);
if(bstr != NULL)
MultiByteToWideChar(CP_ACP, 0, m_pchData, GetData()->nDataLength, bstr, nLen);
#endif
return bstr;
}
inline BSTR CString::SetSysString(BSTR* pbstr) const
{
ATLASSERT(AfxIsValidAddress(pbstr, sizeof(BSTR)));
#if defined(_UNICODE) || defined(OLE2ANSI)
::SysReAllocStringLen(pbstr, m_pchData, GetData()->nDataLength);
#else
int nLen = MultiByteToWideChar(CP_ACP, 0, m_pchData,
GetData()->nDataLength, NULL, NULL);
if(::SysReAllocStringLen(pbstr, NULL, nLen))
MultiByteToWideChar(CP_ACP, 0, m_pchData, GetData()->nDataLength, *pbstr, nLen);
#endif
ATLASSERT(*pbstr != NULL);
return *pbstr;
}
#endif //!_ATL_NO_COM
#endif //!_ATL_TMP_NO_CSTRING
}; //namespace ATL
#endif // __ATLTMP_H__
/////////////////////////////////////////////////////////////////////////////