Windows2003-3790/public/sdk/inc/atl21/atlconv.h
2020-09-30 16:53:55 +02:00

657 lines
22 KiB
C++

// This is a part of the Active Template Library.
// Copyright (C) 1996-1997 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.
#ifndef __ATLCONV_H__
#define __ATLCONV_H__
#ifndef __cplusplus
#error ATL requires C++ compilation (use a .cpp suffix)
#endif
#ifndef _INC_MALLOC
#include <malloc.h>
#endif // _INC_MALLOC
#pragma pack(push,8)
namespace ATL
{
namespace _ATL_SAFE_ALLOCA_IMPL
{
// Following code is to avoid alloca causing a stack overflow.
// It is intended for use from the _ATL_SAFE_ALLOCA macros
// or Conversion macros.
__declspec(selectany) DWORD _Atlosplatform = 0;
inline BOOL _AtlGetVersionEx()
{
OSVERSIONINFO osi;
memset(&osi, 0, sizeof(OSVERSIONINFO));
osi.dwOSVersionInfoSize = sizeof(OSVERSIONINFO);
GetVersionEx(&osi);
_Atlosplatform = osi.dwPlatformId;
return TRUE;
}
// From VC7 CRT sources.
#define _ATL_MIN_STACK_REQ_WIN9X 0x11000
#define _ATL_MIN_STACK_REQ_WINNT 0x2000
/***
* void _resetstkoflw(void) - Recovers from Stack Overflow
*
* Purpose:
* Sets the guard page to its position before the stack overflow.
*
* Exit:
* Returns nonzero on success, zero on failure
*
*******************************************************************************/
inline int _Atlresetstkoflw(void)
{
static BOOL bTemp = _AtlGetVersionEx();
LPBYTE pStack, pGuard, pStackBase, pMaxGuard, pMinGuard;
MEMORY_BASIC_INFORMATION mbi;
SYSTEM_INFO si;
DWORD PageSize;
DWORD flNewProtect;
DWORD flOldProtect;
// Use _alloca() to get the current stack pointer
pStack = (LPBYTE)_alloca(1);
// Find the base of the stack.
if (VirtualQuery(pStack, &mbi, sizeof mbi) == 0)
return 0;
pStackBase = (LPBYTE)mbi.AllocationBase;
// Find the page just below where the stack pointer currently points.
// This is the highest potential guard page.
GetSystemInfo(&si);
PageSize = si.dwPageSize;
pMaxGuard = (LPBYTE) (((DWORD_PTR)pStack & ~(DWORD_PTR)(PageSize - 1))
- PageSize);
// If the potential guard page is too close to the start of the stack
// region, abandon the reset effort for lack of space. Win9x has a
// larger reserved stack requirement.
pMinGuard = pStackBase + ((_Atlosplatform == VER_PLATFORM_WIN32_WINDOWS)
? _ATL_MIN_STACK_REQ_WIN9X
: _ATL_MIN_STACK_REQ_WINNT);
if (pMaxGuard < pMinGuard)
return 0;
// On a non-Win9x system, do nothing if a guard page is already present,
// else set up the guard page to the bottom of the committed range.
// For Win9x, just set guard page below the current stack page.
if (_Atlosplatform != VER_PLATFORM_WIN32_WINDOWS) {
// Find first block of committed memory in the stack region
pGuard = pStackBase;
do {
if (VirtualQuery(pGuard, &mbi, sizeof mbi) == 0)
return 0;
pGuard = pGuard + mbi.RegionSize;
} while ((mbi.State & MEM_COMMIT) == 0);
pGuard = (LPBYTE)mbi.BaseAddress;
// If first committed block is already marked as a guard page,
// there is nothing that needs to be done, so return success.
if (mbi.Protect & PAGE_GUARD)
return 1;
// Fail if the first committed block is above the highest potential
// guard page. Should never happen.
if (pMaxGuard < pGuard)
return 0;
VirtualAlloc(pGuard, PageSize, MEM_COMMIT, PAGE_READWRITE);
}
else {
pGuard = pMaxGuard;
}
// Enable the new guard page.
flNewProtect = _Atlosplatform == VER_PLATFORM_WIN32_WINDOWS
? PAGE_NOACCESS
: PAGE_READWRITE | PAGE_GUARD;
return VirtualProtect(pGuard, PageSize, flNewProtect, &flOldProtect);
}
// Verifies if sufficient space is available on the stack.
inline bool _AtlVerifyStackAvailable(SIZE_T Size)
{
bool bStackAvailable = true;
__try
{
PVOID p = _alloca(Size);
p;
}
__except ((EXCEPTION_STACK_OVERFLOW == GetExceptionCode()) ?
EXCEPTION_EXECUTE_HANDLER :
EXCEPTION_CONTINUE_SEARCH)
{
bStackAvailable = false;
_Atlresetstkoflw();
}
return bStackAvailable;
}
// Helper Classes to manage heap buffers for _ATL_SAFE_ALLOCA
// Default allocator used by ATL
class _CCRTAllocator
{
public :
static void * Allocate(SIZE_T nRequestedSize)
{
return malloc(nRequestedSize);
}
static void Free(void* p)
{
free(p);
}
};
template < class Allocator>
class CAtlSafeAllocBufferManager
{
private :
struct CAtlSafeAllocBufferNode
{
CAtlSafeAllocBufferNode* m_pNext;
void* GetData()
{
return (this + 1);
}
};
CAtlSafeAllocBufferNode* m_pHead;
public :
CAtlSafeAllocBufferManager() : m_pHead(NULL) {};
void* Allocate(SIZE_T nRequestedSize)
{
CAtlSafeAllocBufferNode *p = (CAtlSafeAllocBufferNode*)Allocator::Allocate(nRequestedSize + sizeof(CAtlSafeAllocBufferNode));
if (p == NULL)
return NULL;
// Add buffer to the list
p->m_pNext = m_pHead;
m_pHead = p;
return p->GetData();
}
~CAtlSafeAllocBufferManager()
{
// Walk the list and free the buffers
while (m_pHead != NULL)
{
CAtlSafeAllocBufferNode* p = m_pHead;
m_pHead = m_pHead->m_pNext;
Allocator::Free(p);
}
}
};
// Use one of the following macros before using _ATL_SAFE_ALLOCA
// EX version allows specifying a different heap allocator
#define USES_ATL_SAFE_ALLOCA_EX(x) ATL::_ATL_SAFE_ALLOCA_IMPL::CAtlSafeAllocBufferManager<x> _AtlSafeAllocaManager
#ifndef USES_ATL_SAFE_ALLOCA
#define USES_ATL_SAFE_ALLOCA USES_ATL_SAFE_ALLOCA_EX(ATL::_ATL_SAFE_ALLOCA_IMPL::_CCRTAllocator)
#endif
// nRequestedSize - requested size in bytes
// nThreshold - size in bytes beyond which memory is allocated from the heap.
// Defining _ATL_SAFE_ALLOCA_ALWAYS_ALLOCATE_THRESHOLD_SIZE always allocates the size specified
// for threshold if the stack space is available irrespective of requested size.
// This available for testing purposes. It will help determine the max stack usage due to _alloca's
#ifdef _ATL_SAFE_ALLOCA_ALWAYS_ALLOCATE_THRESHOLD_SIZE
#define _ATL_SAFE_ALLOCA(nRequestedSize, nThreshold) \
(((nRequestedSize) <= (nThreshold) && ATL::_ATL_SAFE_ALLOCA_IMPL::_AtlVerifyStackAvailable(nThreshold) ) ? \
_alloca(nThreshold) : \
((ATL::_ATL_SAFE_ALLOCA_IMPL::_AtlVerifyStackAvailable(nThreshold)) ? _alloca(nThreshold) : 0), \
_AtlSafeAllocaManager.Allocate(nRequestedSize))
#else
#define _ATL_SAFE_ALLOCA(nRequestedSize, nThreshold) \
(((nRequestedSize) <= (nThreshold) && ATL::_ATL_SAFE_ALLOCA_IMPL::_AtlVerifyStackAvailable(nRequestedSize) ) ? \
_alloca(nRequestedSize) : \
_AtlSafeAllocaManager.Allocate(nRequestedSize))
#endif
// Use 1024 bytes as the default threshold in ATL
#ifndef _ATL_SAFE_ALLOCA_DEF_THRESHOLD
#define _ATL_SAFE_ALLOCA_DEF_THRESHOLD 1024
#endif
} // namespace _ATL_SAFE_ALLOCA_IMPL
} // namespace ATL
// Make sure MFC's afxconv.h hasn't already been loaded to do this
#ifndef USES_CONVERSION
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
#ifndef _DEBUG
#define USES_CONVERSION int _convert; _convert
#else
#define USES_CONVERSION int _convert = 0
#endif
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#ifndef _DEBUG
#define USES_CONVERSION_EX int _convert_ex; _convert_ex; UINT _acp_ex = CP_ACP; _acp_ex; LPCWSTR _lpw_ex; _lpw_ex; LPCSTR _lpa_ex; _lpa_ex; USES_ATL_SAFE_ALLOCA
#else
#define USES_CONVERSION_EX int _convert_ex = 0; _convert_ex; UINT _acp_ex = CP_ACP; _acp_ex; LPCWSTR _lpw_ex = NULL; _lpw_ex; LPCSTR _lpa_ex = NULL; _lpa_ex; USES_ATL_SAFE_ALLOCA
#endif
/////////////////////////////////////////////////////////////////////////////
// Global UNICODE<>ANSI translation helpers
LPWSTR WINAPI AtlA2WHelper(LPWSTR lpw, LPCSTR lpa, int nChars);
LPSTR WINAPI AtlW2AHelper(LPSTR lpa, LPCWSTR lpw, int nChars);
#ifndef ATLA2WHELPER
#define ATLA2WHELPER AtlA2WHelper
#define ATLW2AHELPER AtlW2AHelper
#endif
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
#define A2W(lpa) (\
((LPCSTR)lpa == NULL) ? NULL : (\
_convert = (lstrlenA(lpa)+1),\
ATLA2WHELPER((LPWSTR) alloca(_convert*2), (LPCSTR)lpa, _convert)))
#define W2A(lpw) (\
((LPCWSTR)lpw == NULL) ? NULL : (\
_convert = (lstrlenW(lpw)+1)*2,\
ATLW2AHELPER((LPSTR) alloca(_convert), lpw, _convert)))
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
// The call to _alloca will not cause stack overflow if _AtlVerifyStackAvailable returns TRUE.
#define A2W_EX(lpa, nThreshold) (\
((_lpa_ex = lpa) == NULL) ? NULL : (\
_convert_ex = (lstrlenA(_lpa_ex)+1),\
ATLA2WHELPER( \
(LPWSTR)_ATL_SAFE_ALLOCA(_convert_ex * sizeof(WCHAR), nThreshold), \
_lpa_ex, \
_convert_ex)))
#define W2A_EX(lpw, nThreshold) (\
((_lpw_ex = lpw) == NULL) ? NULL : (\
_convert_ex = (lstrlenW(_lpw_ex)+1) * sizeof(WCHAR),\
ATLW2AHELPER( \
(LPSTR)_ATL_SAFE_ALLOCA(_convert_ex, nThreshold), \
_lpw_ex, \
_convert_ex)))
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
#define A2CW(lpa) ((LPCWSTR)A2W(lpa))
#define W2CA(lpw) ((LPCSTR)W2A(lpw))
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#define A2CW_EX(lpa, nChar) ((LPCWSTR)A2W_EX(lpa, nChar))
#define W2CA_EX(lpw, nChar) ((LPCSTR)W2A_EX(lpw, nChar))
#if defined(_UNICODE)
// in these cases the default (TCHAR) is the same as OLECHAR
inline int ocslen(LPCOLESTR x) { return lstrlenW(x); }
inline OLECHAR* ocscpy(LPOLESTR dest, LPCOLESTR src) { return lstrcpyW(dest, src); }
inline LPCOLESTR T2COLE_EX(LPCTSTR lp, UINT) { return lp; }
inline LPCTSTR OLE2CT_EX(LPCOLESTR lp, UINT) { return lp; }
inline LPOLESTR T2OLE_EX(LPTSTR lp, UINT) { return lp; }
inline LPTSTR OLE2T_EX(LPOLESTR lp, UINT) { return lp; }
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
inline LPCOLESTR T2COLE(LPCTSTR lp) { return lp; }
inline LPCTSTR OLE2CT(LPCOLESTR lp) { return lp; }
inline LPOLESTR T2OLE(LPTSTR lp) { return lp; }
inline LPTSTR OLE2T(LPOLESTR lp) { return lp; }
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#elif defined(OLE2ANSI)
// in these cases the default (TCHAR) is the same as OLECHAR
inline int ocslen(LPCOLESTR x) { return lstrlen(x); }
inline OLECHAR* ocscpy(LPOLESTR dest, LPCOLESTR src) { return lstrcpy(dest, src); }
inline LPCOLESTR T2COLE_EX(LPCTSTR lp, UINT) { return lp; }
inline LPCTSTR OLE2CT_EX(LPCOLESTR lp, UINT) { return lp; }
inline LPOLESTR T2OLE_EX(LPTSTR lp, UINT) { return lp; }
inline LPTSTR OLE2T_EX(LPOLESTR lp, UINT) { return lp; }
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
inline LPCOLESTR T2COLE(LPCTSTR lp) { return lp; }
inline LPCTSTR OLE2CT(LPCOLESTR lp) { return lp; }
inline LPOLESTR T2OLE(LPTSTR lp) { return lp; }
inline LPTSTR OLE2T(LPOLESTR lp) { return lp; }
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#else
inline int ocslen(LPCOLESTR x) { return lstrlenW(x); }
//lstrcpyW doesn't work on Win95, so we do this
inline OLECHAR* ocscpy(LPOLESTR dest, LPCOLESTR src)
{return (LPOLESTR) memcpy(dest, src, (lstrlenW(src)+1)*sizeof(WCHAR));}
//CharNextW doesn't work on Win95 so we use this
#define T2COLE_EX(lpa, nChar) A2CW_EX(lpa, nChar)
#define T2OLE_EX(lpa, nChar) A2W_EX(lpa, nChar)
#define OLE2CT_EX(lpo, nChar) W2CA_EX(lpo, nChar)
#define OLE2T_EX(lpo, nChar) W2A_EX(lpo, nChar)
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
#define T2COLE(lpa) A2CW(lpa)
#define T2OLE(lpa) A2W(lpa)
#define OLE2CT(lpo) W2CA(lpo)
#define OLE2T(lpo) W2A(lpo)
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#endif
#ifdef OLE2ANSI
inline LPOLESTR A2OLE_EX(LPSTR lp, UINT) { return lp;}
inline LPSTR OLE2A_EX(LPOLESTR lp, UINT) { return lp;}
#define W2OLE_EX W2A_EX
#define OLE2W_EX A2W_EX
inline LPCOLESTR A2COLE_EX(LPCSTR lp, UINT) { return lp;}
inline LPCSTR OLE2CA_EX(LPCOLESTR lp, UINT) { return lp;}
#define W2COLE_EX W2CA_EX
#define OLE2CW_EX A2CW_EX
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
inline LPOLESTR A2OLE(LPSTR lp) { return lp;}
inline LPSTR OLE2A(LPOLESTR lp) { return lp;}
#define W2OLE W2A
#define OLE2W A2W
inline LPCOLESTR A2COLE(LPCSTR lp) { return lp;}
inline LPCSTR OLE2CA(LPCOLESTR lp) { return lp;}
#define W2COLE W2CA
#define OLE2CW A2CW
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#else
inline LPOLESTR W2OLE_EX(LPWSTR lp, UINT) { return lp; }
inline LPWSTR OLE2W_EX(LPOLESTR lp, UINT) { return lp; }
#define A2OLE_EX A2W_EX
#define OLE2A_EX W2A_EX
inline LPCOLESTR W2COLE_EX(LPCWSTR lp, UINT) { return lp; }
inline LPCWSTR OLE2CW_EX(LPCOLESTR lp, UINT) { return lp; }
#define A2COLE_EX A2CW_EX
#define OLE2CA_EX W2CA_EX
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
inline LPOLESTR W2OLE(LPWSTR lp) { return lp; }
inline LPWSTR OLE2W(LPOLESTR lp) { return lp; }
#define A2OLE A2W
#define OLE2A W2A
inline LPCOLESTR W2COLE(LPCWSTR lp) { return lp; }
inline LPCWSTR OLE2CW(LPCOLESTR lp) { return lp; }
#define A2COLE A2CW
#define OLE2CA W2CA
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#endif
#ifdef _UNICODE
#define T2A_EX W2A_EX
#define A2T_EX A2W_EX
inline LPWSTR T2W_EX(LPTSTR lp, UINT) { return lp; }
inline LPTSTR W2T_EX(LPWSTR lp, UINT) { return lp; }
#define T2CA_EX W2CA_EX
#define A2CT_EX A2CW_EX
inline LPCWSTR T2CW_EX(LPCTSTR lp, UINT) { return lp; }
inline LPCTSTR W2CT_EX(LPCWSTR lp, UINT) { return lp; }
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
#define T2A W2A
#define A2T A2W
inline LPWSTR T2W(LPTSTR lp) { return lp; }
inline LPTSTR W2T(LPWSTR lp) { return lp; }
#define T2CA W2CA
#define A2CT A2CW
inline LPCWSTR T2CW(LPCTSTR lp) { return lp; }
inline LPCTSTR W2CT(LPCWSTR lp) { return lp; }
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#else
#define T2W_EX A2W_EX
#define W2T_EX W2A_EX
inline LPSTR T2A_EX(LPTSTR lp, UINT) { return lp; }
inline LPTSTR A2T_EX(LPSTR lp, UINT) { return lp; }
#define T2CW_EX A2CW_EX
#define W2CT_EX W2CA_EX
inline LPCSTR T2CA_EX(LPCTSTR lp, UINT) { return lp; }
inline LPCTSTR A2CT_EX(LPCSTR lp, UINT) { return lp; }
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
#define T2W A2W
#define W2T W2A
inline LPSTR T2A(LPTSTR lp) { return lp; }
inline LPTSTR A2T(LPSTR lp) { return lp; }
#define T2CW A2CW
#define W2CT W2CA
inline LPCSTR T2CA(LPCTSTR lp) { return lp; }
inline LPCTSTR A2CT(LPCSTR lp) { return lp; }
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#endif
inline BSTR A2WBSTR(LPCSTR lp, int nLen = -1)
{
if (lp == NULL || nLen == 0)
return NULL;
USES_CONVERSION_EX;
BSTR str = NULL;
int nConvertedLen = MultiByteToWideChar(_acp_ex, 0, lp,
nLen, NULL, NULL);
int nAllocLen = nConvertedLen;
if (nLen == -1)
nAllocLen -= 1; // Don't allocate terminating '\0'
str = ::SysAllocStringLen(NULL, nAllocLen);
if (str != NULL)
{
int nResult;
nResult = MultiByteToWideChar(_acp_ex, 0, lp, nLen, str, nConvertedLen);
if(nResult != nConvertedLen)
{
SysFreeString(str);
return NULL;
}
}
return str;
}
inline BSTR OLE2BSTR(LPCOLESTR lp) {return ::SysAllocString(lp);}
#if defined(_UNICODE)
// in these cases the default (TCHAR) is the same as OLECHAR
inline BSTR T2BSTR_EX(LPCTSTR lp) {return ::SysAllocString(lp);}
inline BSTR A2BSTR_EX(LPCSTR lp) {return A2WBSTR(lp);}
inline BSTR W2BSTR_EX(LPCWSTR lp) {return ::SysAllocString(lp);}
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
inline BSTR T2BSTR(LPCTSTR lp) {return T2BSTR_EX(lp); }
inline BSTR A2BSTR(LPCSTR lp) {return A2BSTR_EX(lp); }
inline BSTR W2BSTR(LPCWSTR lp) {return W2BSTR_EX(lp); }
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#elif defined(OLE2ANSI)
// in these cases the default (TCHAR) is the same as OLECHAR
inline BSTR T2BSTR_EX(LPCTSTR lp) {return ::SysAllocString(lp);}
inline BSTR A2BSTR_EX(LPCSTR lp) {return ::SysAllocString(lp);}
inline BSTR W2BSTR_EX(LPCWSTR lp) {USES_CONVERSION_EX; return ::SysAllocString(W2COLE_EX(lp));}
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
inline BSTR T2BSTR(LPCTSTR lp) {return T2BSTR_EX(lp); }
inline BSTR A2BSTR(LPCSTR lp) {return A2BSTR_EX(lp); }
inline BSTR W2BSTR(LPCWSTR lp) {USES_CONVERSION; return ::SysAllocString(W2COLE(lp));}
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#else
inline BSTR T2BSTR_EX(LPCTSTR lp) {return A2WBSTR(lp);}
inline BSTR A2BSTR_EX(LPCSTR lp) {return A2WBSTR(lp);}
inline BSTR W2BSTR_EX(LPCWSTR lp) {return ::SysAllocString(lp);}
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
inline BSTR T2BSTR(LPCTSTR lp) {return T2BSTR_EX(lp); }
inline BSTR A2BSTR(LPCSTR lp) {return A2BSTR_EX(lp); }
inline BSTR W2BSTR(LPCWSTR lp) {return W2BSTR_EX(lp); }
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#endif
#if defined(_WINGDI_) && !defined(NOGDI)
/////////////////////////////////////////////////////////////////////////////
// Global UNICODE<>ANSI translation helpers
LPDEVMODEW AtlDevModeA2W(LPDEVMODEW lpDevModeW, LPDEVMODEA lpDevModeA);
LPDEVMODEA AtlDevModeW2A(LPDEVMODEA lpDevModeA, LPDEVMODEW lpDevModeW);
LPTEXTMETRICW AtlTextMetricA2W(LPTEXTMETRICW lptmW, LPTEXTMETRICA pltmA);
LPTEXTMETRICA AtlTextMetricW2A(LPTEXTMETRICA lptmA, LPTEXTMETRICW pltmW);
#ifndef ATLDEVMODEA2W
#define ATLDEVMODEA2W AtlDevModeA2W
#define ATLDEVMODEW2A AtlDevModeW2A
#define ATLTEXTMETRICA2W AtlTextMetricA2W
#define ATLTEXTMETRICW2A AtlTextMetricW2A
#endif
// Requires USES_CONVERSION_EX or USES_ATL_SAFE_ALLOCA macro before using the _EX versions of the macros
#define DEVMODEW2A_EX(lpw)\
((lpw == NULL) ? NULL : ATLDEVMODEW2A((LPDEVMODEA)_ATL_SAFE_ALLOCA(sizeof(DEVMODEA)+lpw->dmDriverExtra, _ATL_SAFE_ALLOCA_DEF_THRESHOLD), lpw))
#define DEVMODEA2W_EX(lpa)\
((lpa == NULL) ? NULL : ATLDEVMODEA2W((LPDEVMODEW)_ATL_SAFE_ALLOCA(sizeof(DEVMODEW)+lpa->dmDriverExtra, _ATL_SAFE_ALLOCA_DEF_THRESHOLD), lpa))
#define TEXTMETRICW2A_EX(lptmw)\
((lptmw == NULL) ? NULL : ATLTEXTMETRICW2A((LPTEXTMETRICA)_ATL_SAFE_ALLOCA(sizeof(TEXTMETRICA), _ATL_SAFE_ALLOCA_DEF_THRESHOLD), lptmw))
#define TEXTMETRICA2W_EX(lptma)\
((lptma == NULL) ? NULL : ATLTEXTMETRICA2W((LPTEXTMETRICW)_ATL_SAFE_ALLOCA(sizeof(TEXTMETRICW), _ATL_SAFE_ALLOCA_DEF_THRESHOLD), lptma))
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
#define DEVMODEW2A(lpw)\
((lpw == NULL) ? NULL : ATLDEVMODEW2A((LPDEVMODEA)alloca(sizeof(DEVMODEA)+lpw->dmDriverExtra), lpw))
#define DEVMODEA2W(lpa)\
((lpa == NULL) ? NULL : ATLDEVMODEA2W((LPDEVMODEW)alloca(sizeof(DEVMODEW)+lpa->dmDriverExtra), lpa))
#define TEXTMETRICW2A(lptmw)\
((lptmw == NULL) ? NULL : ATLTEXTMETRICW2A((LPTEXTMETRICA)alloca(sizeof(TEXTMETRICA)), lptmw))
#define TEXTMETRICA2W(lptma)\
((lptma == NULL) ? NULL : ATLTEXTMETRICA2W((LPTEXTMETRICW)alloca(sizeof(TEXTMETRICW)), lptma))
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#ifdef OLE2ANSI
#define DEVMODEOLE DEVMODEA
#define LPDEVMODEOLE LPDEVMODEA
#define TEXTMETRICOLE TEXTMETRICA
#define LPTEXTMETRICOLE LPTEXTMETRICA
#else
#define DEVMODEOLE DEVMODEW
#define LPDEVMODEOLE LPDEVMODEW
#define TEXTMETRICOLE TEXTMETRICW
#define LPTEXTMETRICOLE LPTEXTMETRICW
#endif
#if defined(_UNICODE)
// in these cases the default (TCHAR) is the same as OLECHAR
inline LPDEVMODEW DEVMODEOLE2T_EX(LPDEVMODEOLE lp) { return lp; }
inline LPDEVMODEOLE DEVMODET2OLE_EX(LPDEVMODEW lp) { return lp; }
inline LPTEXTMETRICW TEXTMETRICOLE2T_EX(LPTEXTMETRICOLE lp) { return lp; }
inline LPTEXTMETRICOLE TEXTMETRICT2OLE_EX(LPTEXTMETRICW lp) { return lp; }
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
inline LPDEVMODEW DEVMODEOLE2T(LPDEVMODEOLE lp) { return lp; }
inline LPDEVMODEOLE DEVMODET2OLE(LPDEVMODEW lp) { return lp; }
inline LPTEXTMETRICW TEXTMETRICOLE2T(LPTEXTMETRICOLE lp) { return lp; }
inline LPTEXTMETRICOLE TEXTMETRICT2OLE(LPTEXTMETRICW lp) { return lp; }
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#elif defined(OLE2ANSI)
// in these cases the default (TCHAR) is the same as OLECHAR
inline LPDEVMODE DEVMODEOLE2T_EX(LPDEVMODEOLE lp) { return lp; }
inline LPDEVMODEOLE DEVMODET2OLE_EX(LPDEVMODE lp) { return lp; }
inline LPTEXTMETRIC TEXTMETRICOLE2T_EX(LPTEXTMETRICOLE lp) { return lp; }
inline LPTEXTMETRICOLE TEXTMETRICT2OLE_EX(LPTEXTMETRIC lp) { return lp; }
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
inline LPDEVMODE DEVMODEOLE2T(LPDEVMODEOLE lp) { return lp; }
inline LPDEVMODEOLE DEVMODET2OLE(LPDEVMODE lp) { return lp; }
inline LPTEXTMETRIC TEXTMETRICOLE2T(LPTEXTMETRICOLE lp) { return lp; }
inline LPTEXTMETRICOLE TEXTMETRICT2OLE(LPTEXTMETRIC lp) { return lp; }
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#else
#define DEVMODEOLE2T_EX(lpo) DEVMODEW2A_EX(lpo)
#define DEVMODET2OLE_EX(lpa) DEVMODEA2W_EX(lpa)
#define TEXTMETRICOLE2T_EX(lptmw) TEXTMETRICW2A_EX(lptmw)
#define TEXTMETRICT2OLE_EX(lptma) TEXTMETRICA2W_EX(lptma)
#ifndef _ATL_EX_CONVERSION_MACROS_ONLY
#define DEVMODEOLE2T(lpo) DEVMODEW2A(lpo)
#define DEVMODET2OLE(lpa) DEVMODEA2W(lpa)
#define TEXTMETRICOLE2T(lptmw) TEXTMETRICW2A(lptmw)
#define TEXTMETRICT2OLE(lptma) TEXTMETRICA2W(lptma)
#endif // _ATL_EX_CONVERSION_MACROS_ONLY
#endif
#endif //_WINGDI_
#else //!USES_CONVERSION
// if USES_CONVERSION already defined (i.e. MFC_VER < 4.21 )
// flip this switch to avoid atlconv.cpp
#define _ATL_NO_CONVERSIONS
#endif //!USES_CONVERSION
// Define these even if MFC already included
#if defined(_UNICODE)
// in these cases the default (TCHAR) is the same as OLECHAR
inline LPOLESTR CharNextO(LPCOLESTR lp) {return CharNextW(lp);}
#elif defined(OLE2ANSI)
// in these cases the default (TCHAR) is the same as OLECHAR
inline LPOLESTR CharNextO(LPCOLESTR lp) {return CharNext(lp);}
#else
inline LPOLESTR CharNextO(LPCOLESTR lp) {return (LPOLESTR)(lp+1);}
#endif
#pragma pack(pop)
#endif // __ATLCONV_H__
/////////////////////////////////////////////////////////////////////////////