/* * Unicode <--> MultiByte conversions, OLE, and other system functions * * Copyright (c) 1995-1998, Microsoft Corporation. All rights reserved. */ #include // CoCreateInstance define #include "aimm.h" // AIMM i/f #include "aimm_i.c" // AIMM CLSID etc #include "_font.h" #include "_uspi.h" #define MAX_HKLS 256 // It will be a while before we have more KBs static HINSTANCE g_hOleAut32 = NULL; static HINSTANCE g_hOle32 = NULL; #ifndef NOACCESSIBILITY static HINSTANCE g_hAcc = NULL; static HINSTANCE g_hUser32 = NULL; #endif class CIMM32_PROC { public: void *ImmGetCompositionStringA; void *ImmGetCompositionStringW; void *ImmGetContext; void *ImmSetCompositionFontA; void *ImmSetCompositionWindow; void *ImmReleaseContext; void *ImmGetProperty; void *ImmGetCandidateWindow; void *ImmSetCandidateWindow; void *ImmNotifyIME; void *ImmAssociateContext; void *ImmGetVirtualKey; void *ImmEscapeA; void *ImmEscapeW; void *ImmGetOpenStatus; void *ImmSetOpenStatus; void *ImmGetConversionStatus; void *ImmSetConversionStatus; void *ImmGetDefaultIMEWnd; void *ImmSetCompositionStringW; }; static CIMM32_PROC g_IMM32Proc; class CIMESHARE_PROC { public: void *FSupportSty; void *PIMEStyleFromAttr; void *PColorStyleTextFromIMEStyle; void *PColorStyleBackFromIMEStyle; void *FBoldIMEStyle; void *FItalicIMEStyle; void *FUlIMEStyle; void *IdUlIMEStyle; void *RGBFromIMEColorStyle; }; static CIMESHARE_PROC g_IMEShareProc; class COLEAUT32_PROC { public: void *LoadRegTypeLib; void *LoadTypeLib; void *LoadTypeLibEx; void *SysAllocString; void *SysAllocStringLen; void *SysFreeString; void *SysStringLen; void *VariantInit; }; static COLEAUT32_PROC g_OleAut32Proc; class COLE32_PROC { public: void *OleCreateFromData; void *CoTaskMemFree; void *CreateBindCtx; void *OleDuplicateData; void *CoTreatAsClass; void *ProgIDFromCLSID; void *OleConvertIStorageToOLESTREAM; void *OleConvertIStorageToOLESTREAMEx; void *OleSave; void *StgCreateDocfileOnILockBytes; void *CreateILockBytesOnHGlobal; void *OleCreateLinkToFile; void *CoTaskMemAlloc; void *CoTaskMemRealloc; void *OleInitialize; void *OleUninitialize; void *OleSetClipboard; void *OleFlushClipboard; void *OleIsCurrentClipboard; void *DoDragDrop; void *OleGetClipboard; void *RegisterDragDrop; void *OleCreateLinkFromData; void *OleCreateStaticFromData; void *OleDraw; void *OleSetContainedObject; void *CoDisconnectObject; void *WriteFmtUserTypeStg; void *WriteClassStg; void *SetConvertStg; void *ReadFmtUserTypeStg; void *ReadClassStg; void *OleRun; void *RevokeDragDrop; void *CreateStreamOnHGlobal; void *GetHGlobalFromStream; void *OleCreateDefaultHandler; void *CLSIDFromProgID; void *OleConvertOLESTREAMToIStorage; void *OleLoad; void *ReleaseStgMedium; void *CoCreateInstance; }; static COLE32_PROC g_Ole32Proc; class CConvertStr { public: operator char *(); protected: CConvertStr(); ~CConvertStr(); void Free(); LPSTR _pstr; char _ach[MAX_PATH * 2]; }; inline CConvertStr::operator char *() { return _pstr; } inline CConvertStr::CConvertStr() { _pstr = NULL; } inline CConvertStr::~CConvertStr() { Free(); } class CStrIn : public CConvertStr { public: CStrIn(LPCWSTR pwstr, UINT CodePage = CP_ACP); CStrIn(LPCWSTR pwstr, int cwch, UINT CodePage = CP_ACP); int strlen(); protected: CStrIn(); void Init(LPCWSTR pwstr, int cwch, UINT CodePage = CP_ACP); int _cchLen; }; inline CStrIn::CStrIn() { } inline int CStrIn::strlen() { return _cchLen; } class CStrOut : public CConvertStr { public: CStrOut(LPWSTR pwstr, int cwchBuf); ~CStrOut(); int BufSize(); int Convert(); private: LPWSTR _pwstr; int _cwchBuf; }; inline int CStrOut::BufSize() { return _cwchBuf * 2; } // // Multi-Byte ---> Unicode conversion // class CStrOutW : public CConvertStrW { public: CStrOutW(LPSTR pstr, int cchBuf, UINT uiCodePage); ~CStrOutW(); int BufSize(); int Convert(); private: LPSTR _pstr; int _cchBuf; UINT _uiCodePage; }; inline int CStrOutW::BufSize() { return _cchBuf; } DWORD CW32System::AddRef() { return ++_cRefs; } DWORD CW32System::Release() { DWORD culRefs = --_cRefs; if(culRefs == 0) { FreeIME(); if (g_hOle32) { EnterCriticalSection(&g_CriticalSection); OleUninitialize(); FreeLibrary(g_hOle32); g_hOle32 = NULL; memset(&g_Ole32Proc, 0, sizeof(g_Ole32Proc)); LeaveCriticalSection(&g_CriticalSection); } } return culRefs; } ATOM WINAPI CW32System::RegisterREClass( const WNDCLASSW *lpWndClass, const char *szAnsiClassName, WNDPROC AnsiWndProc ) { WNDCLASSA wc; ATOM atom; TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "RegisterREClass"); // First register the normal window class. if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) { atom = ::RegisterClass(lpWndClass); if (!atom && GetLastError() == ERROR_CLASS_ALREADY_EXISTS) atom = FindAtom(lpWndClass->lpszClassName); } else { // On WIndows 95 we need to convert the window class name. CStrIn strMenuName(lpWndClass->lpszMenuName); CStrIn strClassName(lpWndClass->lpszClassName); Assert(sizeof(wc) == sizeof(*lpWndClass)); memcpy(&wc, lpWndClass, sizeof(wc)); wc.lpszMenuName = strMenuName; wc.lpszClassName = strClassName; atom = ::RegisterClassA(&wc); if (!atom && GetLastError() == ERROR_CLASS_ALREADY_EXISTS) atom = FindAtomA(wc.lpszClassName); } if (!atom || !szAnsiClassName) return atom; // Now REgister the ANSI window class name i.e. RICHEDIT20A wc.style = lpWndClass->style; wc.cbClsExtra = lpWndClass->cbClsExtra; wc.cbWndExtra = lpWndClass->cbWndExtra; wc.hInstance = lpWndClass->hInstance; wc.hIcon = lpWndClass->hIcon; wc.hCursor = lpWndClass->hIcon; wc.hbrBackground = lpWndClass->hbrBackground; wc.lpszMenuName = NULL; wc.lpfnWndProc = AnsiWndProc; wc.lpszClassName = szAnsiClassName; atom = ::RegisterClassA(&wc); if (!atom && GetLastError() == ERROR_CLASS_ALREADY_EXISTS) atom = FindAtomA(szAnsiClassName); return atom; } LONG ValidateTextRange(TEXTRANGE *pstrg); LRESULT CW32System::ANSIWndProc( HWND hwnd, UINT msg, WPARAM wparam, LPARAM lparam, BOOL fIs10Mode) { TRACEBEGIN(TRCSUBSYSHOST, TRCSCOPEINTERN, "RichEditANSIWndProc"); #ifdef DEBUG Tracef(TRCSEVINFO, "hwnd %lx, msg %lx, wparam %lx, lparam %lx", hwnd, msg, wparam, lparam); #endif // DEBUG LRESULT lres; switch( msg ) { case EM_REPLACESEL: case WM_SETTEXT: { SETTEXTEX st = {ST_CHECKPROTECTION, 0}; if(msg == EM_REPLACESEL) { st.flags = wparam ? ST_CHECKPROTECTION | ST_SELECTION | ST_KEEPUNDO | ST_10REPLACESEL : ST_CHECKPROTECTION | ST_SELECTION | ST_10REPLACESEL; } else if (fIs10Mode) st.flags |= ST_10WM_SETTEXT; // 1.0 Mode WM_SETTEXT return RichEditWndProc(hwnd, EM_SETTEXTEX, (WPARAM)&st, lparam); } case EM_FINDTEXT: case EM_FINDTEXTEX: { // We cheat a little here because FINDTEXT and FINDTEXTEX overlap // with the exception of the extra out param chrgText in FINDTEXTEX FINDTEXTEXW ftexw; FINDTEXTA *pfta = (FINDTEXTA *)lparam; CStrInW strinw(pfta->lpstrText, W32->GetKeyboardCodePage()); ftexw.chrg = pfta->chrg; ftexw.lpstrText = (WCHAR *)strinw; lres = RichEditWndProc(hwnd, msg, wparam, (LPARAM)&ftexw); if(msg == EM_FINDTEXTEX) { // In the FINDTEXTEX case, the extra field in the // FINDTEXTEX data structure is an out parameter indicating // the range where the text was found. Update the 'real' // [in, out] parameter accordingly. ((FINDTEXTEXA *)lparam)->chrgText = ftexw.chrgText; } return lres; } break; case EM_GETSELTEXT: { GETTEXTEX gt; const char chDefault = ' '; gt.cb = (unsigned)-1; // Client claims to have enuf room gt.flags = GT_SELECTION; // Get selected text gt.codepage = (unsigned)-1; // Use default CCharFormat codepage gt.lpDefaultChar = &chDefault; // Translate other chars into blanks gt.lpUsedDefChar = NULL; return RichEditWndProc(hwnd, EM_GETTEXTEX, (WPARAM)>, lparam); } break; // case WM_GETTEXT: Handled by Ansi filter // case WM_GETTEXTLENGTH: Handled by Ansi filter case EM_GETTEXTRANGE: { TEXTRANGEA *ptrg = (TEXTRANGEA *)lparam; LONG clInBuffer = ValidateTextRange((TEXTRANGEW *) ptrg); // If size is -1, this means that the size required is the total // size of the the text. if(-1 == clInBuffer) { // We can get this length either by digging the data out of the // various structures below us or we can take advantage of the // WM_GETTEXTLENGTH message. The first might be slightly // faster but the second definitely save code size. So we // will go with the second. clInBuffer = SendMessage(hwnd, WM_GETTEXTLENGTH, 0, 0); } if(0 == clInBuffer) { // The buffer was invalid for some reason or there was not data // to copy. In any case, we are done. return 0; } // Verify that the output buffer is big enough. if(IsBadWritePtr(ptrg->lpstrText, clInBuffer + 1)) { // Not enough space so don't copy any return 0; } // For EM_GETTEXTRANGE case, we again don't know how big the // incoming buffer is, only that it should be *at least* as // great as cpMax - cpMin in the text range structure. We also // know that anything *bigger* than (cpMax - cpMin)*2 bytes is // uncessary. So we'll just assume that it's "big enough" // and let WideCharToMultiByte scribble as much as it needs. // Memory shortages are the caller's responsibility (courtesy // of the RichEdit 1.0 design). CStrOutW stroutw(ptrg->lpstrText, (clInBuffer + 1) * sizeof(WCHAR), RichEditWndProc(hwnd, EM_GETCODEPAGE, 0, 0)); TEXTRANGEW trgw; trgw.chrg = ptrg->chrg; trgw.lpstrText = (WCHAR *)stroutw; RichEditWndProc(hwnd, EM_GETTEXTRANGE, wparam, (LPARAM)&trgw); return stroutw.Convert(); // Return count of BYTEs converted } case EM_GETLINE: { // The size is indicated by the first word of the memory pointed // to by lparam WORD size = *(WORD *)lparam; CStrOutW stroutw((char *)lparam, (DWORD)size, RichEditWndProc(hwnd, EM_GETCODEPAGE, 0, 0)); WCHAR *pwsz = (WCHAR *)stroutw; *(WORD *)pwsz = size; lres = RichEditWndProc(hwnd, msg, wparam, (LPARAM)pwsz); if (lres < size) *(pwsz+lres) = L'\0'; // EM_GETLINE does not return NULL-terminated string. LONG cach = stroutw.Convert(); // Note: should probably return cach for 3.0 too, i.e., // just like EM_GETTEXTRANGE above return fIs10Mode ? cach : lres; // If 1.0, return count of BYTEs converted } #ifdef DEBUG case WM_NCCREATE: case WM_CREATE: // These messages should be handled higher up so let everyone // know we got to the wrong place! AssertSz(FALSE, "CW32System::ANSIWndProc got WM_CREATE or WM_NCCREATE"); break; #endif // DEBUG } return RichEditWndProc(hwnd, msg, wparam, lparam); } // Note that AnsiFilter could be refined so that we could get rid // of the ANSI window proc. void CW32System::AnsiFilter( UINT & msg, WPARAM &wparam, LPARAM lparam, void *pvoid, BOOL f10Mode ) { GETTEXTEX *pgt; GETTEXTLENGTHEX *pgtl; WM_CHAR_INFO *pwmci; bool fAltNumPad = (GetKeyboardFlags() & ALTNUMPAD) != 0; UINT cpg = GetKeyboardCodePage(0xFFFFFFFF); switch (msg) { case WM_CHAR: pwmci = (WM_CHAR_INFO *) pvoid; pwmci->_fTrailByte = false; pwmci->_fLeadByte = false; pwmci->_fIMEChar = false; if (pwmci->_fAccumulate) { // We could do some validation here. pwmci->_fTrailByte = true; return; } // WM_CHAR > 256 on Win95; assumed to be Unicode if(fAltNumPad) { DWORD Number = GetKeyPadNumber(); if(Number >= 256 || GetKeyboardFlags() & ALT0) { wparam = Number; if(!IN_RANGE(1250, cpg, 1258)) // Use 1252 for DBCS cpg = 1252; // codepages } } if(IN_RANGE(128, wparam, 255)) { bool fShift = (GetKeyboardFlags() & SHIFT) != 0; bool fCtrl = (GetKeyboardFlags() & CTRL) != 0; // If fAltNumPad is set, wparam is HiAnsi // If Shift + Alt + Ctrl, it is repeat event from Win3.1 IME if ((!fAltNumPad || (fShift && fCtrl)) && GetTrailBytesCount((BYTE) wparam, cpg)) { pwmci->_fLeadByte = true; return; } WPARAM wparamNew = 0; switch ( cpg ) { case CP_JAPAN: // for Japanese codepage, need to translate SBC if KANA mode is on if ((GetKeyState(VK_KANA) & 1) || f10Mode) break; // If not in KANA mode, then fall thru to use 1252 codepage... case CP_KOREAN: case CP_CHINESE_TRAD: case CP_CHINESE_SIM: // use English codepage since there is no HiAnsi conversion for // FE systems cpg = 1252; break; } if (cpg == 1252 && !IN_RANGE(0x80, wparam, 0x9f)) return; // Convert single byte WM_CHAR messages to Unicode if(UnicodeFromMbcs((LPWSTR)&wparamNew, 1, (char *)&wparam, 1, cpg) == 1 ) { wparam = wparamNew; if (fAltNumPad) SetKeyPadNumber(wparam); } } else if(lparam == 1 && _dwPlatformId == VER_PLATFORM_WIN32_NT && wparam > 256 && !fAltNumPad) { // On WinNT s/w generated WM_CHAR, this should be WM_IME_CHAR message // for some Chinese Level 2 IME. if ( cpg == CP_CHINESE_SIM || cpg == CP_CHINESE_TRAD ) { BYTE bTrailByte = wparam >> 8; BYTE bLeadByte = wparam; wparam = (bLeadByte << 8) | bTrailByte; pwmci->_fIMEChar = true; } } return; case WM_GETTEXT: // EVIL HACK ALERT: on Win95, WM_GETTEXT should always be treated // as an ANSI message. pgt = (GETTEXTEX *) pvoid; pgt->cb = wparam; pgt->flags = GT_USECRLF; pgt->codepage = 0; pgt->lpDefaultChar = NULL; pgt->lpUsedDefChar = NULL; msg = EM_GETTEXTEX; wparam = (WPARAM) pgt; return; case WM_GETTEXTLENGTH: // EVIL HACK ALERT: on Win95, WM_GETEXTLENGTH should always // be treated an ANSI message because some old apps will send // this message to arbitrary windows (e.g., accessibility aps) pgtl = (GETTEXTLENGTHEX *) pvoid; pgtl->flags = GTL_NUMBYTES | GTL_PRECISE | GTL_USECRLF; pgtl->codepage = 0; msg = EM_GETTEXTLENGTHEX; wparam = (WPARAM) pgtl; return; } } HGLOBAL WINAPI CW32System::GlobalAlloc( UINT uFlags, DWORD dwBytes ) { return ::GlobalAlloc( uFlags, dwBytes ); } HGLOBAL WINAPI CW32System::GlobalFree( HGLOBAL hMem ) { return hMem ? ::GlobalFree( hMem ) : NULL; } UINT WINAPI CW32System::GlobalFlags( HGLOBAL hMem ) { return ::GlobalFlags( hMem ); } HGLOBAL WINAPI CW32System::GlobalReAlloc( HGLOBAL hMem, DWORD dwBytes, UINT uFlags ) { return ::GlobalReAlloc( hMem, dwBytes, uFlags ); } DWORD WINAPI CW32System::GlobalSize( HGLOBAL hMem ) { return ::GlobalSize( hMem ); } LPVOID WINAPI CW32System::GlobalLock( HGLOBAL hMem ) { return ::GlobalLock( hMem ); } HGLOBAL WINAPI CW32System::GlobalHandle( LPCVOID pMem ) { return ::GlobalHandle( pMem ); } BOOL WINAPI CW32System::GlobalUnlock( HGLOBAL hMem ) { return ::GlobalUnlock( hMem ); } /* * CW32System::CheckChangeKeyboardLayout (bCharSet) * * @mfunc * Change keyboard for new charset, or charset at new character position. * * @rdesc * Keyboard hkl selected. 0 if failed to find keyboard * * @comm * Using only the currently loaded KBs, locate one that will support * bCharSet. This is called anytime a character format change occurs, * or the caret position changes. * * @devnote * The current KB is preferred. If a previous association was made, * see if the KB is still loaded in the system and if so use it. * Otherwise, locate a suitable KB, preferring KB's that have * the same charset ID as their default, preferred charset. If no * match can be found, nothing changes. */ HKL CW32System::CheckChangeKeyboardLayout( BYTE bCharSet) { return ActivateKeyboard(ScriptIndexFromCharSet(bCharSet)); } HKL CW32System::GetKeyboardLayout ( DWORD dwThreadID) { if(dwThreadID == 0x0FFFFFFFF) RefreshKeyboardLayout(); return _hklCurrent; } /* * CW32System::RefreshKeyboardLayout () * * @mfunc * Update _hklCurrent with current keyboard layout and update * entry for corresponding script. */ void CW32System::RefreshKeyboardLayout () { INT iScript; _hklCurrent = ::GetKeyboardLayout(0); GetCharSet(ConvertLanguageIDtoCodePage(PRIMARYLANGID(_hklCurrent)), &iScript); SetPreferredKbd(iScript, _hklCurrent); } /* * CW32System::ActivateKeyboard (iScript) * * @mfunc * Change keyboard to that for iScript * * @rdesc * Keyboard hkl selected. 0 if no keyboard assigned to iScript */ HKL CW32System::ActivateKeyboard( LONG iScript) { HKL hkl = 0; if((unsigned)iScript < NCHARSETS) { hkl = GetPreferredKbd(iScript); if(hkl && hkl != _hklCurrent && ActivateKeyboardLayout(hkl, 0)) _hklCurrent = hkl; } return hkl; } /* * CW32System::FindDirectionalKeyboard (fRTL) * * @mfunc * Find first keyboard with direction given by fRTL * * @rdesc * HKL of keyboard selected. 0 if no keyboard for direction given by fRTL */ HKL CW32System::FindDirectionalKeyboard( BOOL fRTL) { Assert(ARABIC_INDEX == (HEBREW_INDEX | 1)); int iKB; if(fRTL) { GetCharSet(GetACP(), &iKB); if(!IN_RANGE(HEBREW_INDEX, iKB, ARABIC_INDEX)) iKB = _hkl[HEBREW_INDEX] ? HEBREW_INDEX : _hkl[ARABIC_INDEX] ? ARABIC_INDEX : -1; } else for(iKB = 0; iKB < NCHARSETS && (!_hkl[iKB] || IN_RANGE(HEBREW_INDEX, iKB, ARABIC_INDEX)); iKB++) ; return ActivateKeyboard(iKB); } enum DLL_ENUM{ DLL_OLEAUT32, DLL_OLE32, #ifndef NOACCESSIBILITY DLL_ACC, DLL_USER32 #endif }; static void SetProcAddr( void * & pfunc, DLL_ENUM which, char * fname ) { HINSTANCE hdll = NULL; EnterCriticalSection(&g_CriticalSection); if (pfunc == NULL) { switch (which) { case DLL_OLEAUT32: if (g_hOleAut32 == NULL) g_hOleAut32 = W32->LoadLibrary(L"oleaut32.dll" ); hdll = g_hOleAut32; break; case DLL_OLE32: if (g_hOle32 == NULL) { g_hOle32 = W32->LoadLibrary(L"ole32.dll"); CW32System::OleInitialize(NULL); } hdll = g_hOle32; break; #ifndef NOACCESSIBILITY case DLL_ACC: if (g_hAcc == NULL) g_hAcc = W32->LoadLibrary(L"oleacc.dll"); hdll = g_hAcc; break; case DLL_USER32: if (g_hUser32 == NULL) g_hUser32 = W32->LoadLibrary(L"user32.dll"); hdll = g_hUser32; break; #endif } Assert(hdll != NULL || which == DLL_USER32); pfunc = GetProcAddress( hdll, fname ); } AssertSz(pfunc != NULL || which == DLL_USER32, fname); LeaveCriticalSection(&g_CriticalSection); } void CW32System::FreeOle() { if (g_hOleAut32 || g_hOle32) { EnterCriticalSection(&g_CriticalSection); if (g_hOleAut32 != NULL && FreeLibrary(g_hOleAut32)) { g_hOleAut32 = NULL; memset(&g_OleAut32Proc, 0, sizeof(g_OleAut32Proc)); } if (g_hOle32 != NULL && FreeLibrary(g_hOle32)) { g_hOle32 = NULL; memset(&g_Ole32Proc, 0, sizeof(g_Ole32Proc)); } LeaveCriticalSection(&g_CriticalSection); } } enum IME_DLL_ENUM{ DLL_IMM32, DLL_IMESHARE }; static HINSTANCE hIMM32 = NULL; static HINSTANCE hIMEShare = NULL; static void SetIMEProcAddr( void * &pfunc, IME_DLL_ENUM which, char * fname ) { HINSTANCE hdll = NULL; EnterCriticalSection(&g_CriticalSection); if (pfunc == NULL) { switch (which) { case DLL_IMM32 : if (hIMM32 == NULL) hIMM32 = W32->LoadLibrary(L"imm32.dll" ); Assert( hIMM32 != NULL ); hdll = hIMM32; break; case DLL_IMESHARE : if (hIMEShare == NULL) hIMEShare = W32->LoadLibrary(L"imeshare.dll" ); else if (hIMEShare == (HINSTANCE)INVALID_HANDLE_VALUE) goto Exit; hdll = hIMEShare; // set to invalid handle if we have tried loading it. // this is to avoid loading it again and again in case // imeshare.dll is not in the system. if (hIMEShare == NULL) hIMEShare = (HINSTANCE)INVALID_HANDLE_VALUE; break; } if (hdll) { pfunc = GetProcAddress( hdll, fname ); Assert(pfunc != NULL ); } } Exit: LeaveCriticalSection(&g_CriticalSection); } static IActiveIMMApp *pAIMM = (IActiveIMMApp *) NULL; typedef IMESHAREAPI void (IMECDECL*FEND_CAST)(void); void CW32System::FreeIME() { if (hIMM32 || hIMEShare || pAIMM) { EnterCriticalSection(&g_CriticalSection); if (hIMM32 != NULL && FreeLibrary(hIMM32)) { hIMM32 = NULL; memset(&g_IMM32Proc, 0, sizeof(g_IMM32Proc)); } if (hIMEShare != NULL && hIMEShare != (HINSTANCE)INVALID_HANDLE_VALUE) { // clean up IMMShare before leaving if ( _pIMEShare ) { _pIMEShare->FDeleteIMEShare(); _pIMEShare = NULL; } else { // This is old IMEShare, end it the old way void *pEndIMEShareFunc; pEndIMEShareFunc = GetProcAddress( hIMEShare, "EndIMEShare" ); if (pEndIMEShareFunc) { ( (FEND_CAST)pEndIMEShareFunc)(); } } FreeLibrary(hIMEShare); hIMEShare = NULL; memset(&g_IMEShareProc, 0, sizeof(g_IMEShareProc)); } if (pAIMM != (IActiveIMMApp *)NULL && pAIMM != (IActiveIMMApp *)INVALID_HANDLE_VALUE) { pAIMM->Release(); pAIMM = (IActiveIMMApp *)NULL; } _fHaveAIMM = FALSE; _fHaveIMMEShare = FALSE; _fHaveIMMProcs = FALSE; LeaveCriticalSection(&g_CriticalSection); } } // return TRUE if we load AIMM BOOL CW32System::LoadAIMM() { HRESULT hResult; // return if AIMM has been loaded if (_fHaveAIMM) return TRUE; if (pAIMM == (IActiveIMMApp *)INVALID_HANDLE_VALUE) return FALSE; EnterCriticalSection(&g_CriticalSection); // load if it has not been loaded // Try with new W2K/COM+ CLSCTX_NO_CODE_DOWNLOAD flag hResult = CW32System::CoCreateInstance(CLSID_CActiveIMM, NULL, CLSCTX_INPROC_SERVER | CLSCTX_NO_CODE_DOWNLOAD, IID_IActiveIMMApp, (LPVOID *)&pAIMM); if (hResult == E_INVALIDARG) // Try again if CLSCTX_NO_CODE_DOWNLOAD not support hResult = CW32System::CoCreateInstance(CLSID_CActiveIMM, NULL, CLSCTX_INPROC_SERVER, IID_IActiveIMMApp, (LPVOID *)&pAIMM); _fHaveAIMM = TRUE; if (FAILED(hResult)) { _fHaveAIMM = FALSE; pAIMM = (IActiveIMMApp *)INVALID_HANDLE_VALUE; } LeaveCriticalSection(&g_CriticalSection); return _fHaveAIMM; } // Return the Aimm object and AddRef() BOOL CW32System::GetAimmObject(IUnknown **ppAimm) { *ppAimm = NULL; if (pAIMM != NULL && pAIMM != (IActiveIMMApp *)INVALID_HANDLE_VALUE) { pAIMM->AddRef(); *ppAimm = pAIMM; return TRUE; } return FALSE; } // return TRUE if we have IMEShare in system // else return FALSE typedef IMESHAREAPI BOOL (IMECDECL*FINIT_CAST)(void); typedef IMESHAREAPI CIMEShare * (IMECDECL*FPIME_CAST)(void); BOOL CW32System::HaveIMEShare() { // return if IMEShare has been loaded if (_fHaveIMMEShare) return TRUE; if (hIMEShare == (HINSTANCE)INVALID_HANDLE_VALUE) return FALSE; EnterCriticalSection(&g_CriticalSection); // load if it has not been loaded hIMEShare = W32->LoadLibrary(L"imeshare.dll"); _fHaveIMMEShare = TRUE; // load fail, setup INVALID_HANDLE_VALUE if (hIMEShare == NULL) { hIMEShare = (HINSTANCE)INVALID_HANDLE_VALUE; _fHaveIMMEShare = FALSE; } else { // get the new IMEshare object and init the DLL void *pPIMEShareCreate; pPIMEShareCreate = GetProcAddress( hIMEShare, "PIMEShareCreate" ); if (pPIMEShareCreate) { _pIMEShare = ( (FPIME_CAST)pPIMEShareCreate) (); if ( _pIMEShare == NULL ) _fHaveIMMEShare = FALSE; else { // Setup underline styles that RE supports for (int i = IMESTY_UL_MIN; i <= IMESTY_UL_MAX; i++) { if (i == 2004 || i == 2007 || i == 2008 || i == 2009 || i == 2010) // Obsolete styles continue; _pIMEShare->FSupportSty(i, i); } } } else { // This is old IMEShare, init it the old way void *pInitFunc; pInitFunc = GetProcAddress( hIMEShare, "FInitIMEShare" ); if (pInitFunc) { _fHaveIMMEShare = ( (FINIT_CAST)pInitFunc)(); } else // init failed, forget it _fHaveIMMEShare = FALSE; } if (_fHaveIMMEShare == FALSE) { // Init failed, forget it FreeLibrary(hIMEShare); hIMEShare = (HINSTANCE)INVALID_HANDLE_VALUE; } } LeaveCriticalSection(&g_CriticalSection); return _fHaveIMMEShare; } BOOL CW32System::getIMEShareObject(CIMEShare **ppIMEShare) { *ppIMEShare = _pIMEShare; return (_pIMEShare != NULL); } HRESULT CW32System::AIMMDefWndProc(HWND hWnd, UINT msg, WPARAM wparam, LPARAM lparam, LRESULT *plres) { if (pAIMM != NULL && pAIMM != (IActiveIMMApp *)INVALID_HANDLE_VALUE) { HRESULT hResult; LRESULT localLRes; hResult = pAIMM->OnDefWindowProc(hWnd, msg, wparam, lparam, &localLRes); if (hResult == S_OK) { *plres = localLRes; return S_OK; } } return S_FALSE; } HRESULT CW32System::AIMMGetCodePage(HKL hKL, UINT *uCodePage) { if (pAIMM != NULL && pAIMM != (IActiveIMMApp *)INVALID_HANDLE_VALUE) { HRESULT hResult; hResult = pAIMM->GetCodePageA(hKL, uCodePage); if (SUCCEEDED(hResult)) return S_OK; } return S_FALSE; } HRESULT CW32System::AIMMActivate(BOOL fRestoreLayout) { if (pAIMM != NULL && pAIMM != (IActiveIMMApp *)INVALID_HANDLE_VALUE) { HRESULT hResult; hResult = pAIMM->Activate(fRestoreLayout); if (SUCCEEDED(hResult)) return S_OK; } return S_FALSE; } HRESULT CW32System::AIMMDeactivate(void) { if (pAIMM != NULL && pAIMM != (IActiveIMMApp *)INVALID_HANDLE_VALUE) { HRESULT hResult; hResult = pAIMM->Deactivate(); if (SUCCEEDED(hResult)) return S_OK; } return S_FALSE; } HRESULT CW32System::AIMMFilterClientWindows(ATOM *aaClassList, UINT uSize) { if (pAIMM != NULL && pAIMM != (IActiveIMMApp *)INVALID_HANDLE_VALUE) { HRESULT hResult; hResult = pAIMM->FilterClientWindows(aaClassList, uSize); if (SUCCEEDED(hResult)) return S_OK; } return S_FALSE; } #define RE_OLEAUTAPI(name) DECLSPEC_IMPORT HRESULT (STDAPICALLTYPE *name) #define RE_OLEAUTAPI_(type, name) DECLSPEC_IMPORT type (STDAPICALLTYPE *name) typedef RE_OLEAUTAPI(LRTL_CAST)(REFGUID, WORD, WORD, LCID, ITypeLib **); HRESULT CW32System::LoadRegTypeLib ( REFGUID rguid, WORD wmajor, WORD wminor, LCID lcid, ITypeLib ** pptlib ) { if (g_OleAut32Proc.LoadRegTypeLib == NULL) SetProcAddr( g_OleAut32Proc.LoadRegTypeLib, DLL_OLEAUT32, "LoadRegTypeLib" ); return ((LRTL_CAST)g_OleAut32Proc.LoadRegTypeLib)(rguid, wmajor, wminor, lcid, pptlib); } typedef RE_OLEAUTAPI(LTL_CAST)(const OLECHAR *, ITypeLib **); HRESULT CW32System::LoadTypeLib ( const OLECHAR *szfile, ITypeLib **pptlib ) { if (g_OleAut32Proc.LoadTypeLib == NULL) SetProcAddr( g_OleAut32Proc.LoadTypeLib, DLL_OLEAUT32, "LoadTypeLib" ); return ((LTL_CAST)g_OleAut32Proc.LoadTypeLib)(szfile, pptlib); } typedef RE_OLEAUTAPI(LTLEX_CAST)(const OLECHAR *, REGKIND, ITypeLib **); HRESULT CW32System::LoadTypeLibEx ( const OLECHAR *szfile, REGKIND regkind, ITypeLib **pptlib ) { if (g_OleAut32Proc.LoadTypeLibEx == NULL) SetProcAddr( g_OleAut32Proc.LoadTypeLibEx, DLL_OLEAUT32, "LoadTypeLibEx" ); return ((LTLEX_CAST)g_OleAut32Proc.LoadTypeLibEx)(szfile, regkind, pptlib); } typedef RE_OLEAUTAPI_(BSTR, SAS_CAST)(const OLECHAR *); BSTR CW32System::SysAllocString ( const OLECHAR * sz ) { if (g_OleAut32Proc.SysAllocString == NULL) SetProcAddr( g_OleAut32Proc.SysAllocString, DLL_OLEAUT32, "SysAllocString" ); return ((SAS_CAST)g_OleAut32Proc.SysAllocString)(sz); } typedef RE_OLEAUTAPI_(BSTR, SASL_CAST)(const OLECHAR *, UINT); BSTR CW32System::SysAllocStringLen ( const OLECHAR *pch, UINT cch ) { if (g_OleAut32Proc.SysAllocStringLen == NULL) SetProcAddr( g_OleAut32Proc.SysAllocStringLen, DLL_OLEAUT32, "SysAllocStringLen" ); return ((SASL_CAST)g_OleAut32Proc.SysAllocStringLen)(pch, cch); } typedef RE_OLEAUTAPI_(void, SFS_CAST)(BSTR); void CW32System::SysFreeString ( BSTR bstr ) { if (g_OleAut32Proc.SysFreeString == NULL) SetProcAddr( g_OleAut32Proc.SysFreeString, DLL_OLEAUT32, "SysFreeString" ); ((SFS_CAST)g_OleAut32Proc.SysFreeString)(bstr); } typedef RE_OLEAUTAPI_(UINT, SSL_CAST)(BSTR); UINT CW32System::SysStringLen ( BSTR bstr ) { if (g_OleAut32Proc.SysStringLen == NULL) SetProcAddr( g_OleAut32Proc.SysStringLen, DLL_OLEAUT32, "SysStringLen" ); return ((SSL_CAST)g_OleAut32Proc.SysStringLen)(bstr); } typedef RE_OLEAUTAPI_(void, VI_CAST)(VARIANTARG *); void CW32System::VariantInit ( VARIANTARG * pvarg ) { if (g_OleAut32Proc.VariantInit == NULL) SetProcAddr( g_OleAut32Proc.VariantInit, DLL_OLEAUT32, "VariantInit" ); ((VI_CAST)g_OleAut32Proc.VariantInit)(pvarg); } #define RE_OLE32API(name) DECLSPEC_IMPORT HRESULT (STDAPICALLTYPE *name) #define RE_OLE32API_(type, name) DECLSPEC_IMPORT type (STDAPICALLTYPE *name) typedef RE_OLE32API(OCFD_CAST)(LPDATAOBJECT, REFIID, DWORD, LPFORMATETC, LPOLECLIENTSITE, LPSTORAGE, void **); HRESULT CW32System::OleCreateFromData ( LPDATAOBJECT pDataObj, REFIID riid, DWORD renderopt, LPFORMATETC pfetc, LPOLECLIENTSITE pClientSite, LPSTORAGE pStg, void **ppvObj ) { if (g_Ole32Proc.OleCreateFromData == NULL) SetProcAddr( g_Ole32Proc.OleCreateFromData, DLL_OLE32, "OleCreateFromData" ); return ((OCFD_CAST)g_Ole32Proc.OleCreateFromData)(pDataObj, riid, renderopt, pfetc, pClientSite, pStg, ppvObj); } typedef RE_OLE32API_(void, CTMF_CAST)(LPVOID); void CW32System::CoTaskMemFree ( LPVOID pv ) { if (g_Ole32Proc.CoTaskMemFree == NULL) SetProcAddr( g_Ole32Proc.CoTaskMemFree, DLL_OLE32, "CoTaskMemFree" ); ((CTMF_CAST)g_Ole32Proc.CoTaskMemFree)(pv); } typedef RE_OLE32API(CBC_CAST)(DWORD, LPBC *); HRESULT CW32System::CreateBindCtx ( DWORD reserved, LPBC * ppbc ) { if (g_Ole32Proc.CreateBindCtx == NULL) SetProcAddr( g_Ole32Proc.CreateBindCtx, DLL_OLE32, "CreateBindCtx" ); return ((CBC_CAST)g_Ole32Proc.CreateBindCtx)(reserved, ppbc); } typedef RE_OLE32API_(HANDLE, ODD_CAST)(HANDLE, CLIPFORMAT, UINT); HANDLE CW32System::OleDuplicateData ( HANDLE hSrc, CLIPFORMAT cfFormat, UINT uFlags ) { if (g_Ole32Proc.OleDuplicateData == NULL) SetProcAddr( g_Ole32Proc.OleDuplicateData, DLL_OLE32, "OleDuplicateData" ); return ((ODD_CAST)g_Ole32Proc.OleDuplicateData)(hSrc, cfFormat, uFlags); } typedef RE_OLE32API(CTAC_CAST)(REFCLSID, REFCLSID); HRESULT CW32System::CoTreatAsClass ( REFCLSID clsidold, REFCLSID clsidnew ) { if (g_Ole32Proc.CoTreatAsClass == NULL) SetProcAddr( g_Ole32Proc.CoTreatAsClass, DLL_OLE32, "CoTreatAsClass" ); return ((CTAC_CAST)g_Ole32Proc.CoTreatAsClass)(clsidold, clsidnew); } typedef RE_OLE32API(PIFC_CAST)(REFCLSID, LPOLESTR *); HRESULT CW32System::ProgIDFromCLSID ( REFCLSID clsid, LPOLESTR * lplpszProgId ) { if (g_Ole32Proc.ProgIDFromCLSID == NULL) SetProcAddr( g_Ole32Proc.ProgIDFromCLSID, DLL_OLE32, "ProgIDFromCLSID" ); return ((PIFC_CAST)g_Ole32Proc.ProgIDFromCLSID)(clsid, lplpszProgId); } typedef RE_OLE32API(OCITO_CAST)(LPSTORAGE, LPOLESTREAM); HRESULT CW32System::OleConvertIStorageToOLESTREAM ( LPSTORAGE pstg, LPOLESTREAM lpolestream) { if (g_Ole32Proc.OleConvertIStorageToOLESTREAM == NULL) SetProcAddr( g_Ole32Proc.OleConvertIStorageToOLESTREAM, DLL_OLE32, "OleConvertIStorageToOLESTREAM" ); return ((OCITO_CAST)g_Ole32Proc.OleConvertIStorageToOLESTREAM)(pstg, lpolestream); } typedef RE_OLE32API(OCITOX_CAST)(LPSTORAGE, CLIPFORMAT, LONG, LONG, DWORD, LPSTGMEDIUM, LPOLESTREAM); HRESULT CW32System::OleConvertIStorageToOLESTREAMEx ( LPSTORAGE pstg, CLIPFORMAT cf, LONG lwidth, LONG lheight, DWORD dwsize, LPSTGMEDIUM pmedium, LPOLESTREAM lpolestream ) { if (g_Ole32Proc.OleConvertIStorageToOLESTREAMEx == NULL) SetProcAddr( g_Ole32Proc.OleConvertIStorageToOLESTREAMEx, DLL_OLE32, "OleConvertIStorageToOLESTREAMEx" ); return ((OCITOX_CAST)g_Ole32Proc.OleConvertIStorageToOLESTREAMEx) (pstg,cf, lwidth, lheight, dwsize, pmedium, lpolestream); } typedef RE_OLE32API(OS_CAST)(LPPERSISTSTORAGE, LPSTORAGE, BOOL); HRESULT CW32System::OleSave ( LPPERSISTSTORAGE pPS, LPSTORAGE pstg, BOOL fSameAsLoad ) { if (g_Ole32Proc.OleSave == NULL) SetProcAddr( g_Ole32Proc.OleSave, DLL_OLE32, "OleSave" ); return ((OS_CAST)g_Ole32Proc.OleSave)(pPS, pstg, fSameAsLoad); } typedef RE_OLE32API(SCDOI_CAST)(ILockBytes *, DWORD, DWORD, IStorage **); HRESULT CW32System::StgCreateDocfileOnILockBytes ( ILockBytes *plkbyt, DWORD grfmode, DWORD res, IStorage **ppstg ) { if (g_Ole32Proc.StgCreateDocfileOnILockBytes == NULL) SetProcAddr( g_Ole32Proc.StgCreateDocfileOnILockBytes, DLL_OLE32, "StgCreateDocfileOnILockBytes" ); return ((SCDOI_CAST)g_Ole32Proc.StgCreateDocfileOnILockBytes)(plkbyt, grfmode, res, ppstg); } typedef RE_OLE32API(CIOH_CAST)(HGLOBAL, BOOL, ILockBytes **); HRESULT CW32System::CreateILockBytesOnHGlobal ( HGLOBAL hGlobal, BOOL fDel, ILockBytes **pplkbyt ) { if (g_Ole32Proc.CreateILockBytesOnHGlobal == NULL) SetProcAddr( g_Ole32Proc.CreateILockBytesOnHGlobal, DLL_OLE32, "CreateILockBytesOnHGlobal" ); return ((CIOH_CAST)g_Ole32Proc.CreateILockBytesOnHGlobal)(hGlobal, fDel, pplkbyt); } typedef RE_OLE32API(OCLTF_CAST)(LPCOLESTR, REFIID, DWORD, LPFORMATETC, LPOLECLIENTSITE, LPSTORAGE, void **); HRESULT CW32System::OleCreateLinkToFile( LPCOLESTR pstr, REFIID rid, DWORD renderopt, LPFORMATETC pfetc, LPOLECLIENTSITE psite, LPSTORAGE pstg, void **ppstg ) { if (g_Ole32Proc.OleCreateLinkToFile == NULL) SetProcAddr( g_Ole32Proc.OleCreateLinkToFile, DLL_OLE32, "OleCreateLinkToFile" ); return ((OCLTF_CAST)g_Ole32Proc.OleCreateLinkToFile)(pstr, rid, renderopt, pfetc, psite, pstg, ppstg); } typedef RE_OLE32API_(LPVOID, CTMA_CAST)(ULONG); LPVOID CW32System::CoTaskMemAlloc ( ULONG cb ) { if (g_Ole32Proc.CoTaskMemAlloc == NULL) SetProcAddr( g_Ole32Proc.CoTaskMemAlloc, DLL_OLE32, "CoTaskMemAlloc" ); return ((CTMA_CAST)g_Ole32Proc.CoTaskMemAlloc)(cb); } typedef RE_OLE32API_(LPVOID, CTMR_CAST)(LPVOID, ULONG); LPVOID CW32System::CoTaskMemRealloc ( LPVOID pv, ULONG cv) { if (g_Ole32Proc.CoTaskMemRealloc == NULL) SetProcAddr( g_Ole32Proc.CoTaskMemRealloc, DLL_OLE32, "CoTaskMemRealloc" ); return ((CTMR_CAST)g_Ole32Proc.CoTaskMemRealloc)(pv, cv); } typedef RE_OLE32API(OI_CAST)(LPVOID); HRESULT CW32System::OleInitialize ( LPVOID pvres ) { if (g_Ole32Proc.OleInitialize == NULL) SetProcAddr( g_Ole32Proc.OleInitialize, DLL_OLE32, "OleInitialize" ); return ((OI_CAST)g_Ole32Proc.OleInitialize)(pvres); } typedef RE_OLE32API_(void, OUI_CAST)( void ); void CW32System::OleUninitialize ( void ) { if (g_Ole32Proc.OleUninitialize == NULL) SetProcAddr( g_Ole32Proc.OleUninitialize, DLL_OLE32, "OleUninitialize" ); ((OUI_CAST)g_Ole32Proc.OleUninitialize)(); } typedef RE_OLE32API(OSC_CAST)(IDataObject *); HRESULT CW32System::OleSetClipboard ( IDataObject *pdo ) { if (g_Ole32Proc.OleSetClipboard == NULL) SetProcAddr( g_Ole32Proc.OleSetClipboard, DLL_OLE32, "OleSetClipboard" ); return ((OSC_CAST)g_Ole32Proc.OleSetClipboard)(pdo); } typedef RE_OLE32API(OFC_CAST)(void); HRESULT CW32System::OleFlushClipboard ( void ) { if (g_Ole32Proc.OleFlushClipboard == NULL) SetProcAddr( g_Ole32Proc.OleFlushClipboard, DLL_OLE32, "OleFlushClipboard" ); return ((OFC_CAST)g_Ole32Proc.OleFlushClipboard)(); } typedef RE_OLE32API(OICC_CAST)(IDataObject *); HRESULT CW32System::OleIsCurrentClipboard ( IDataObject *pdo ) { if (g_Ole32Proc.OleIsCurrentClipboard == NULL) SetProcAddr( g_Ole32Proc.OleIsCurrentClipboard, DLL_OLE32, "OleIsCurrentClipboard" ); return ((OICC_CAST)g_Ole32Proc.OleIsCurrentClipboard)(pdo); } typedef RE_OLE32API(DDD_CAST)(IDataObject *, IDropSource *, DWORD, DWORD *); HRESULT CW32System::DoDragDrop ( IDataObject *pdo, IDropSource *pds, DWORD dweffect, DWORD *pdweffect ) { if (g_Ole32Proc.DoDragDrop == NULL) SetProcAddr( g_Ole32Proc.DoDragDrop, DLL_OLE32, "DoDragDrop" ); return ((DDD_CAST)g_Ole32Proc.DoDragDrop)(pdo, pds, dweffect, pdweffect); } typedef RE_OLE32API(OGC_CAST)(IDataObject **); HRESULT CW32System::OleGetClipboard ( IDataObject **ppdo ) { if (g_Ole32Proc.OleGetClipboard == NULL) SetProcAddr( g_Ole32Proc.OleGetClipboard, DLL_OLE32, "OleGetClipboard" ); return ((OGC_CAST)g_Ole32Proc.OleGetClipboard)(ppdo); } typedef RE_OLE32API(RDD_CAST)(HWND, IDropTarget *); HRESULT CW32System::RegisterDragDrop ( HWND hwnd, IDropTarget *pdt ) { if (g_Ole32Proc.RegisterDragDrop == NULL) SetProcAddr( g_Ole32Proc.RegisterDragDrop, DLL_OLE32, "RegisterDragDrop" ); return ((RDD_CAST)g_Ole32Proc.RegisterDragDrop)(hwnd, pdt); } typedef RE_OLE32API(OCLFD_CAST)(IDataObject *, REFIID, DWORD, LPFORMATETC, IOleClientSite *, IStorage *, void **); HRESULT CW32System::OleCreateLinkFromData ( IDataObject *pdo, REFIID rid, DWORD renderopt, LPFORMATETC pfetc, IOleClientSite *psite, IStorage *pstg, void **ppv ) { if (g_Ole32Proc.OleCreateLinkFromData == NULL) SetProcAddr( g_Ole32Proc.OleCreateLinkFromData, DLL_OLE32, "OleCreateLinkFromData" ); return ((OCLFD_CAST)g_Ole32Proc.OleCreateLinkFromData) (pdo, rid, renderopt, pfetc, psite, pstg, ppv); } typedef RE_OLE32API(OCSFD_CAST)(IDataObject *, REFIID, DWORD, LPFORMATETC, IOleClientSite *, IStorage *, void **); HRESULT CW32System::OleCreateStaticFromData ( IDataObject *pdo, REFIID rid, DWORD renderopt, LPFORMATETC pfetc, IOleClientSite *psite, IStorage *pstg, void **ppv ) { if (g_Ole32Proc.OleCreateStaticFromData == NULL) SetProcAddr( g_Ole32Proc.OleCreateStaticFromData, DLL_OLE32, "OleCreateStaticFromData" ); return ((OCSFD_CAST)g_Ole32Proc.OleCreateStaticFromData) (pdo, rid, renderopt, pfetc, psite, pstg, ppv); } typedef RE_OLE32API(OD_CAST)(IUnknown *, DWORD, HDC, LPCRECT); HRESULT CW32System::OleDraw ( IUnknown *punk, DWORD dwAspect, HDC hdc, LPCRECT prect ) { if (g_Ole32Proc.OleDraw == NULL) SetProcAddr( g_Ole32Proc.OleDraw, DLL_OLE32, "OleDraw" ); return ((OD_CAST)g_Ole32Proc.OleDraw)(punk, dwAspect, hdc, prect); } typedef RE_OLE32API(OSCO_CAST)(IUnknown *, BOOL); HRESULT CW32System::OleSetContainedObject ( IUnknown *punk, BOOL fContained ) { if (g_Ole32Proc.OleSetContainedObject == NULL) SetProcAddr( g_Ole32Proc.OleSetContainedObject, DLL_OLE32, "OleSetContainedObject" ); return ((OSCO_CAST)g_Ole32Proc.OleSetContainedObject)(punk, fContained); } typedef RE_OLE32API(CDO_CAST)(IUnknown *, DWORD); HRESULT CW32System::CoDisconnectObject ( IUnknown *punk, DWORD dwres ) { if (g_Ole32Proc.CoDisconnectObject == NULL) SetProcAddr( g_Ole32Proc.CoDisconnectObject, DLL_OLE32, "CoDisconnectObject" ); return ((CDO_CAST)g_Ole32Proc.CoDisconnectObject)(punk, dwres); } typedef RE_OLE32API(WFUTS_CAST)(IStorage *, CLIPFORMAT, LPOLESTR); HRESULT CW32System::WriteFmtUserTypeStg ( IStorage *pstg, CLIPFORMAT cf, LPOLESTR pstr) { if (g_Ole32Proc.WriteFmtUserTypeStg == NULL) SetProcAddr( g_Ole32Proc.WriteFmtUserTypeStg, DLL_OLE32, "WriteFmtUserTypeStg" ); return ((WFUTS_CAST)g_Ole32Proc.WriteFmtUserTypeStg)(pstg, cf, pstr); } typedef RE_OLE32API(WCS_CAST)(IStorage *, REFCLSID); HRESULT CW32System::WriteClassStg ( IStorage *pstg, REFCLSID rid ) { if (g_Ole32Proc.WriteClassStg == NULL) SetProcAddr( g_Ole32Proc.WriteClassStg, DLL_OLE32, "WriteClassStg" ); return ((WCS_CAST)g_Ole32Proc.WriteClassStg)(pstg, rid); } typedef RE_OLE32API(SCS_CAST)(IStorage *, BOOL); HRESULT CW32System::SetConvertStg ( IStorage *pstg, BOOL fConv ) { if (g_Ole32Proc.SetConvertStg == NULL) SetProcAddr( g_Ole32Proc.SetConvertStg, DLL_OLE32, "SetConvertStg" ); return ((SCS_CAST)g_Ole32Proc.SetConvertStg)(pstg, fConv); } typedef RE_OLE32API(RFUTS_CAST)(IStorage *, CLIPFORMAT *, LPOLESTR *); HRESULT CW32System::ReadFmtUserTypeStg ( IStorage *pstg, CLIPFORMAT *pcf, LPOLESTR *pstr ) { if (g_Ole32Proc.ReadFmtUserTypeStg == NULL) SetProcAddr( g_Ole32Proc.ReadFmtUserTypeStg, DLL_OLE32, "ReadFmtUserTypeStg" ); return ((RFUTS_CAST)g_Ole32Proc.ReadFmtUserTypeStg)(pstg, pcf, pstr); } typedef RE_OLE32API(RCS_CAST)(IStorage *, CLSID *); HRESULT CW32System::ReadClassStg ( IStorage *pstg, CLSID *pclsid ) { if (g_Ole32Proc.ReadClassStg == NULL) SetProcAddr( g_Ole32Proc.ReadClassStg, DLL_OLE32, "ReadClassStg" ); return ((RCS_CAST)g_Ole32Proc.ReadClassStg)(pstg, pclsid); } typedef RE_OLE32API(OR_CAST)(IUnknown *); HRESULT CW32System::OleRun ( IUnknown *punk ) { if (g_Ole32Proc.OleRun == NULL) SetProcAddr( g_Ole32Proc.OleRun, DLL_OLE32, "OleRun" ); return ((OR_CAST)g_Ole32Proc.OleRun)(punk); } typedef RE_OLE32API(RevDD_CAST)(HWND); HRESULT CW32System::RevokeDragDrop ( HWND hwnd ) { if (g_Ole32Proc.RevokeDragDrop == NULL) SetProcAddr( g_Ole32Proc.RevokeDragDrop, DLL_OLE32, "RevokeDragDrop" ); return ((RevDD_CAST)g_Ole32Proc.RevokeDragDrop)(hwnd); } typedef RE_OLE32API(CSOH_CAST)(HGLOBAL, BOOL, IStream **); HRESULT CW32System::CreateStreamOnHGlobal ( HGLOBAL hglobal, BOOL fDel, IStream **ppstrm ) { if (g_Ole32Proc.CreateStreamOnHGlobal == NULL) SetProcAddr( g_Ole32Proc.CreateStreamOnHGlobal, DLL_OLE32, "CreateStreamOnHGlobal" ); return ((CSOH_CAST)g_Ole32Proc.CreateStreamOnHGlobal)(hglobal, fDel, ppstrm); } typedef RE_OLE32API(GHFS_CAST)(IStream *, HGLOBAL *); HRESULT CW32System::GetHGlobalFromStream ( IStream *pstrm, HGLOBAL *phglobal ) { if (g_Ole32Proc.GetHGlobalFromStream == NULL) SetProcAddr( g_Ole32Proc.GetHGlobalFromStream, DLL_OLE32, "GetHGlobalFromStream" ); return ((GHFS_CAST)g_Ole32Proc.GetHGlobalFromStream)(pstrm, phglobal); } typedef RE_OLE32API(OCDH_CAST)(REFCLSID, IUnknown *, REFIID, void **); HRESULT CW32System::OleCreateDefaultHandler ( REFCLSID clsid, IUnknown *punk, REFIID riid, void **ppv ) { if (g_Ole32Proc.OleCreateDefaultHandler == NULL) SetProcAddr( g_Ole32Proc.OleCreateDefaultHandler, DLL_OLE32, "OleCreateDefaultHandler" ); return ((OCDH_CAST)g_Ole32Proc.OleCreateDefaultHandler)(clsid, punk, riid, ppv); } typedef RE_OLE32API(CFPI_CAST)(LPCOLESTR, LPCLSID); HRESULT CW32System::CLSIDFromProgID ( LPCOLESTR pstr, LPCLSID pclsid ) { if (g_Ole32Proc.CLSIDFromProgID == NULL) SetProcAddr( g_Ole32Proc.CLSIDFromProgID, DLL_OLE32, "CLSIDFromProgID" ); return ((CFPI_CAST)g_Ole32Proc.CLSIDFromProgID)(pstr, pclsid); } typedef RE_OLE32API(OCOTI_CAST)(LPOLESTREAM, IStorage *, const DVTARGETDEVICE *); HRESULT CW32System::OleConvertOLESTREAMToIStorage ( LPOLESTREAM pstrm, IStorage *pstg, const DVTARGETDEVICE *ptd ) { if (g_Ole32Proc.OleConvertOLESTREAMToIStorage == NULL) SetProcAddr( g_Ole32Proc.OleConvertOLESTREAMToIStorage, DLL_OLE32, "OleConvertOLESTREAMToIStorage" ); return ((OCOTI_CAST)g_Ole32Proc.OleConvertOLESTREAMToIStorage)(pstrm, pstg, ptd); } typedef RE_OLE32API(OL_CAST)(IStorage *, REFIID, IOleClientSite *, void **); HRESULT CW32System::OleLoad ( IStorage *pstg, REFIID riid, IOleClientSite *psite, void **ppv ) { if (g_Ole32Proc.OleLoad == NULL) SetProcAddr( g_Ole32Proc.OleLoad, DLL_OLE32, "OleLoad" ); return ((OL_CAST)g_Ole32Proc.OleLoad)(pstg, riid, psite, ppv); } typedef RE_OLE32API(RSM_CAST)(LPSTGMEDIUM); HRESULT CW32System::ReleaseStgMedium ( LPSTGMEDIUM pmedium ) { if (g_Ole32Proc.ReleaseStgMedium == NULL) SetProcAddr( g_Ole32Proc.ReleaseStgMedium, DLL_OLE32, "ReleaseStgMedium" ); return ((RSM_CAST)g_Ole32Proc.ReleaseStgMedium)(pmedium); } typedef RE_OLE32API(CCI_CAST)(REFCLSID, LPUNKNOWN, DWORD, REFIID, LPVOID); HRESULT CW32System::CoCreateInstance (REFCLSID rclsid, LPUNKNOWN pUnknown, DWORD dwClsContext, REFIID riid, LPVOID *ppv) { if (g_Ole32Proc.CoCreateInstance == NULL) SetProcAddr( g_Ole32Proc.CoCreateInstance, DLL_OLE32, "CoCreateInstance" ); return ((CCI_CAST)g_Ole32Proc.CoCreateInstance)(rclsid, pUnknown, dwClsContext, riid, ppv); } BOOL CW32System::ImmInitialize( void ) { // MAC Only function. return FALSE; } void CW32System::ImmTerminate( void ) { // MAC only function. return; } #ifndef NOACCESSIBILITY typedef HRESULT (WINAPI *ACC_VC_CAST)(VARIANTARG FAR*, VARIANTARG FAR*); HRESULT CW32System::VariantCopy(VARIANTARG FAR* pvargDest, VARIANTARG FAR* pvargSrc) { static void *pVariantCopy = NULL; if (pVariantCopy == NULL) SetProcAddr( pVariantCopy, DLL_OLEAUT32, "VariantCopy" ); if (pVariantCopy) return ((ACC_VC_CAST)pVariantCopy)(pvargDest, pvargSrc); return (E_NOINTERFACE); } typedef LRESULT (WINAPI *ACC_LFO_CAST)(REFIID, WPARAM, LPUNKNOWN); LRESULT CW32System::LResultFromObject(REFIID riid, WPARAM wParam, LPUNKNOWN punk) { static void *pLResultFromObject = NULL; if (pLResultFromObject == NULL) SetProcAddr( pLResultFromObject, DLL_ACC, "LresultFromObject" ); if (pLResultFromObject) return ((ACC_LFO_CAST)pLResultFromObject)(riid, wParam, punk); return E_NOINTERFACE; } typedef HRESULT (WINAPI *ACC_AOFW_CAST)(HWND, DWORD, REFIID, void **); HRESULT CW32System::AccessibleObjectFromWindow (HWND hWnd, DWORD dwID, REFIID riidInterface, void ** ppvObject) { static void *pAccessibleObjectFromWindow = NULL; if (pAccessibleObjectFromWindow == NULL) SetProcAddr( pAccessibleObjectFromWindow, DLL_ACC, "AccessibleObjectFromWindow" ); if (pAccessibleObjectFromWindow) return ((ACC_AOFW_CAST)pAccessibleObjectFromWindow)(hWnd, dwID, riidInterface, ppvObject); return (E_NOINTERFACE); } typedef BOOL (WINAPI *ACC_BI_CAST)(BOOL); BOOL CW32System::BlockInput (BOOL fBlock) { static void *pBlockInput = NULL; if (pBlockInput == NULL) SetProcAddr( pBlockInput, DLL_USER32, "BlockInput" ); if (pBlockInput) return ((ACC_BI_CAST)pBlockInput)(fBlock); return FALSE; } typedef UINT (WINAPI *ACC_SI_CAST)(UINT, LPINPUT, int); UINT CW32System::SendInput (UINT nInputs, LPINPUT pInputs, int cbSize) { static void *pSendInput = NULL; if (pSendInput == NULL) SetProcAddr( pSendInput, DLL_USER32, "SendInput" ); if (pSendInput) return ((ACC_SI_CAST)pSendInput)(nInputs, pInputs, cbSize); return 0; } typedef VOID (WINAPI *ACC_NWE_CAST)(DWORD, HWND, LONG, LONG); VOID CW32System::NotifyWinEvent(DWORD dwEvent, HWND hWnd, LONG lObjectType, LONG lObjectId) { static void *pNotfiyWinEvent = NULL; if (pNotfiyWinEvent == INVALID_HANDLE_VALUE) return; if (pNotfiyWinEvent == NULL) SetProcAddr( pNotfiyWinEvent, DLL_USER32, "NotifyWinEvent" ); if (pNotfiyWinEvent) ((ACC_NWE_CAST)pNotfiyWinEvent)(dwEvent, hWnd, lObjectType, lObjectId); else pNotfiyWinEvent = INVALID_HANDLE_VALUE; } #endif typedef LONG (WINAPI*IGCSA_CAST)(HIMC, DWORD, LPVOID, DWORD); LONG CW32System::ImmGetCompositionStringA ( HIMC hIMC, DWORD dwIndex, LPVOID lpBuf, DWORD dwBufLen, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; LONG lCopied = 0; hResult = pAIMM->GetCompositionStringA(hIMC, dwIndex, dwBufLen, &lCopied, lpBuf); return (SUCCEEDED(hResult) ? lCopied : 0); } if (g_IMM32Proc.ImmGetCompositionStringA == NULL) SetIMEProcAddr( g_IMM32Proc.ImmGetCompositionStringA, DLL_IMM32, "ImmGetCompositionStringA" ); return ((IGCSA_CAST)g_IMM32Proc.ImmGetCompositionStringA)(hIMC, dwIndex, lpBuf, dwBufLen); } typedef LONG (WINAPI*IGCSW_CAST)(HIMC, DWORD, LPVOID, DWORD); LONG CW32System::ImmGetCompositionStringW ( HIMC hIMC, DWORD dwIndex, LPVOID lpBuf, DWORD dwBufLen, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; LONG lCopied = 0; hResult = pAIMM->GetCompositionStringW(hIMC, dwIndex, dwBufLen, &lCopied, lpBuf); return (SUCCEEDED(hResult) ? lCopied : 0); } if (g_IMM32Proc.ImmGetCompositionStringW == NULL) SetIMEProcAddr( g_IMM32Proc.ImmGetCompositionStringW, DLL_IMM32, "ImmGetCompositionStringW" ); return ((IGCSW_CAST)g_IMM32Proc.ImmGetCompositionStringW)(hIMC, dwIndex, lpBuf, dwBufLen); } typedef HIMC (WINAPI*IGC_CAST)(HWND); HIMC CW32System::ImmGetContext ( HWND hWnd ) { if (IsAIMMLoaded()) { HRESULT hResult; HIMC hIMC = 0; hResult = pAIMM->GetContext(hWnd, &hIMC); return (SUCCEEDED(hResult) ? hIMC : 0); } if (g_IMM32Proc.ImmGetContext == NULL) SetIMEProcAddr( g_IMM32Proc.ImmGetContext, DLL_IMM32, "ImmGetContext" ); return ((IGC_CAST)g_IMM32Proc.ImmGetContext)(hWnd); } typedef BOOL (WINAPI*ISCFA_CAST)(HIMC, LPLOGFONTA); BOOL CW32System::ImmSetCompositionFontA ( HIMC hIMC, LPLOGFONTA lpLogFontA, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; hResult = pAIMM->SetCompositionFontA(hIMC, lpLogFontA); return (SUCCEEDED(hResult)); } if (g_IMM32Proc.ImmSetCompositionFontA == NULL) SetIMEProcAddr( g_IMM32Proc.ImmSetCompositionFontA, DLL_IMM32, "ImmSetCompositionFontA" ); return ((ISCFA_CAST)g_IMM32Proc.ImmSetCompositionFontA)(hIMC, lpLogFontA); } typedef BOOL (WINAPI*ISCW_CAST)(HIMC, LPCOMPOSITIONFORM); BOOL CW32System::ImmSetCompositionWindow ( HIMC hIMC, LPCOMPOSITIONFORM lpCompForm, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; hResult = pAIMM->SetCompositionWindow(hIMC, lpCompForm); return (SUCCEEDED(hResult)); } if (g_IMM32Proc.ImmSetCompositionWindow == NULL) SetIMEProcAddr( g_IMM32Proc.ImmSetCompositionWindow, DLL_IMM32, "ImmSetCompositionWindow" ); return ((ISCW_CAST)g_IMM32Proc.ImmSetCompositionWindow)(hIMC, lpCompForm); } typedef BOOL (WINAPI*IRC_CAST)(HWND, HIMC); BOOL CW32System::ImmReleaseContext ( HWND hWnd, HIMC hIMC) { if (IsAIMMLoaded()) { HRESULT hResult; hResult = pAIMM->ReleaseContext(hWnd, hIMC); return (SUCCEEDED(hResult)); } if (g_IMM32Proc.ImmReleaseContext == NULL) SetIMEProcAddr( g_IMM32Proc.ImmReleaseContext, DLL_IMM32, "ImmReleaseContext" ); return ((IRC_CAST)g_IMM32Proc.ImmReleaseContext)(hWnd, hIMC); } typedef DWORD (WINAPI*IGP_CAST)(HKL, DWORD); DWORD CW32System::ImmGetProperty ( HKL hKL, DWORD dwIndex, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; DWORD dwProperties=0; hResult = pAIMM->GetProperty(hKL, dwIndex, &dwProperties); return (SUCCEEDED(hResult) ? dwProperties : 0); } if (g_IMM32Proc.ImmGetProperty == NULL) SetIMEProcAddr( g_IMM32Proc.ImmGetProperty, DLL_IMM32, "ImmGetProperty" ); return ((IGP_CAST)g_IMM32Proc.ImmGetProperty)(hKL, dwIndex); } typedef BOOL (WINAPI*IGCW_CAST)(HIMC, DWORD, LPCANDIDATEFORM); BOOL CW32System::ImmGetCandidateWindow ( HIMC hIMC, DWORD dwIndex, LPCANDIDATEFORM lpCandidate, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; hResult = pAIMM->GetCandidateWindow(hIMC, dwIndex, lpCandidate); return (SUCCEEDED(hResult)); } if (g_IMM32Proc.ImmGetCandidateWindow == NULL) SetIMEProcAddr( g_IMM32Proc.ImmGetCandidateWindow, DLL_IMM32, "ImmGetCandidateWindow" ); return ((IGCW_CAST)g_IMM32Proc.ImmGetCandidateWindow)(hIMC, dwIndex, lpCandidate); } typedef BOOL (WINAPI*ISCAW_CAST)(HIMC, LPCANDIDATEFORM); BOOL CW32System::ImmSetCandidateWindow ( HIMC hIMC, LPCANDIDATEFORM lpCandidate , BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; hResult = pAIMM->SetCandidateWindow(hIMC, lpCandidate); return (SUCCEEDED(hResult)); } if (g_IMM32Proc.ImmSetCandidateWindow == NULL) SetIMEProcAddr( g_IMM32Proc.ImmSetCandidateWindow, DLL_IMM32, "ImmSetCandidateWindow" ); return ((ISCAW_CAST)g_IMM32Proc.ImmSetCandidateWindow)(hIMC, lpCandidate); } typedef BOOL (WINAPI*INIME_CAST)(HIMC, DWORD, DWORD, DWORD); BOOL CW32System::ImmNotifyIME ( HIMC hIMC, DWORD dwAction, DWORD dwIndex, DWORD dwValue, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; hResult = pAIMM->NotifyIME(hIMC, dwAction, dwIndex, dwValue); return (SUCCEEDED(hResult)); } if (g_IMM32Proc.ImmNotifyIME == NULL) SetIMEProcAddr( g_IMM32Proc.ImmNotifyIME, DLL_IMM32, "ImmNotifyIME" ); return ((INIME_CAST)g_IMM32Proc.ImmNotifyIME)(hIMC, dwAction, dwIndex, dwValue); } typedef HIMC (WINAPI*IAC_CAST)(HWND, HIMC); HIMC CW32System::ImmAssociateContext ( HWND hWnd, HIMC hIMC, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; HIMC hPreviousIMC=0; hResult = pAIMM->AssociateContext(hWnd, hIMC, &hPreviousIMC); return (SUCCEEDED(hResult) ? hPreviousIMC : 0); } if (g_IMM32Proc.ImmAssociateContext == NULL) SetIMEProcAddr( g_IMM32Proc.ImmAssociateContext, DLL_IMM32, "ImmAssociateContext" ); return ((IAC_CAST)g_IMM32Proc.ImmAssociateContext)(hWnd, hIMC); } typedef UINT (WINAPI*IGVK_CAST)(HWND); UINT CW32System::ImmGetVirtualKey ( HWND hWnd, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; UINT uVirtualKey=0; hResult = pAIMM->GetVirtualKey(hWnd, &uVirtualKey); return (SUCCEEDED(hResult) ? uVirtualKey : 0); } if (g_IMM32Proc.ImmGetVirtualKey == NULL) SetIMEProcAddr( g_IMM32Proc.ImmGetVirtualKey, DLL_IMM32, "ImmGetVirtualKey" ); return ((IGVK_CAST)g_IMM32Proc.ImmGetVirtualKey)(hWnd); } // NOTE: We only use ImmEscape for IME_ESC_HANJA_MODE. // Need to fix up if other methods are used. typedef HIMC (WINAPI*IES_CAST)(HKL, HIMC, UINT, LPVOID ); HIMC CW32System::ImmEscape ( HKL hKL, HIMC hIMC, UINT uEscape, LPVOID lpData, BOOL bAimmActivated) { char szaHangeul[3] = {0, 0, 0}; // Aimm only support A version.. if (!OnWin9x() && !bAimmActivated) goto USE_W_VERSION; if (MbcsFromUnicode(szaHangeul, sizeof(szaHangeul), (LPCWSTR)lpData, 1, CP_KOREAN, UN_NOOBJECTS) <= 0) return FALSE; if (bAimmActivated) { HRESULT hResult; LRESULT lResult=0; hResult = pAIMM->EscapeA(hKL, hIMC, uEscape, (LPVOID)szaHangeul, &lResult); return (SUCCEEDED(hResult) ? (HIMC)lResult : 0); } if (g_IMM32Proc.ImmEscapeA == NULL) SetIMEProcAddr( g_IMM32Proc.ImmEscapeA, DLL_IMM32, "ImmEscapeA" ); return ((IES_CAST)g_IMM32Proc.ImmEscapeA)(hKL, hIMC, uEscape, (LPVOID)szaHangeul); USE_W_VERSION: if (g_IMM32Proc.ImmEscapeW == NULL) SetIMEProcAddr( g_IMM32Proc.ImmEscapeW, DLL_IMM32, "ImmEscapeW" ); return ((IES_CAST)g_IMM32Proc.ImmEscapeW)(hKL, hIMC, uEscape, lpData); } typedef BOOL (WINAPI*IGOS_CAST)(HIMC); BOOL CW32System::ImmGetOpenStatus ( HIMC hIMC, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; // AIMM is returning S_OK for OpenStatus == TRUE. hResult = pAIMM->GetOpenStatus(hIMC); return (hResult == S_OK); } if (g_IMM32Proc.ImmGetOpenStatus == NULL) SetIMEProcAddr( g_IMM32Proc.ImmGetOpenStatus, DLL_IMM32, "ImmGetOpenStatus" ); return ((IGOS_CAST)g_IMM32Proc.ImmGetOpenStatus)(hIMC); } typedef BOOL (WINAPI*ISOS_CAST)(HIMC, BOOL); BOOL CW32System::ImmSetOpenStatus ( HIMC hIMC, BOOL fOpen, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; hResult = pAIMM->SetOpenStatus(hIMC, fOpen); return (SUCCEEDED(hResult)); } if (g_IMM32Proc.ImmSetOpenStatus == NULL) SetIMEProcAddr( g_IMM32Proc.ImmSetOpenStatus, DLL_IMM32, "ImmSetOpenStatus" ); return ((ISOS_CAST)g_IMM32Proc.ImmSetOpenStatus)(hIMC, fOpen); } typedef BOOL (WINAPI*IGCS_CAST)(HIMC , LPDWORD , LPDWORD ); BOOL CW32System::ImmGetConversionStatus ( HIMC hIMC, LPDWORD pdwConversion, LPDWORD pdwSentence, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; hResult = pAIMM->GetConversionStatus(hIMC, pdwConversion, pdwSentence); return (SUCCEEDED(hResult)); } if (g_IMM32Proc.ImmGetConversionStatus == NULL) SetIMEProcAddr( g_IMM32Proc.ImmGetConversionStatus, DLL_IMM32, "ImmGetConversionStatus" ); return ((IGCS_CAST)g_IMM32Proc.ImmGetConversionStatus)(hIMC, pdwConversion, pdwSentence); } typedef BOOL (WINAPI*ISCS_CAST)(HIMC , DWORD , DWORD ); BOOL CW32System::ImmSetConversionStatus ( HIMC hIMC, DWORD dwConversion, DWORD dwSentence, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; hResult = pAIMM->SetConversionStatus(hIMC, dwConversion, dwSentence); return (SUCCEEDED(hResult)); } if (g_IMM32Proc.ImmSetConversionStatus == NULL) SetIMEProcAddr( g_IMM32Proc.ImmSetConversionStatus, DLL_IMM32, "ImmSetConversionStatus" ); return ((ISCS_CAST)g_IMM32Proc.ImmSetConversionStatus)(hIMC, dwConversion, dwSentence); } typedef HWND (WINAPI*IGDW_CAST)( HWND ); HWND CW32System::ImmGetDefaultIMEWnd ( HWND hWnd, BOOL bAimmActivated) { if (bAimmActivated) { HRESULT hResult; HWND hIMEWnd; hResult = pAIMM->GetDefaultIMEWnd(hWnd, &hIMEWnd); return SUCCEEDED(hResult) ? hIMEWnd : NULL; } if (g_IMM32Proc.ImmGetDefaultIMEWnd == NULL) SetIMEProcAddr( g_IMM32Proc.ImmGetDefaultIMEWnd, DLL_IMM32, "ImmGetDefaultIMEWnd" ); return ((IGDW_CAST)g_IMM32Proc.ImmGetDefaultIMEWnd)(hWnd); } typedef BOOL (WINAPI*ISCSW_CAST)(HIMC, DWORD, LPVOID, DWORD, LPVOID, DWORD); BOOL CW32System::ImmSetCompositionStringW ( HIMC hIMC, DWORD dwIndex, LPVOID lpBuf, DWORD dwBufLen, LPVOID lpRead, DWORD dwReadLen) { if (g_IMM32Proc.ImmSetCompositionStringW == NULL) SetIMEProcAddr( g_IMM32Proc.ImmSetCompositionStringW, DLL_IMM32, "ImmSetCompositionStringW" ); return ((ISCSW_CAST)g_IMM32Proc.ImmSetCompositionStringW)(hIMC, dwIndex, lpBuf, dwBufLen, lpRead, dwReadLen); } typedef IMESHAREAPI BOOL (*FSS_CAST)(UINT, UINT); BOOL CW32System::FSupportSty ( UINT uSty, UINT uStyAltered) { if (g_IMEShareProc.FSupportSty == NULL) SetIMEProcAddr( g_IMEShareProc.FSupportSty, DLL_IMESHARE, "FSupportSty" ); return ((FSS_CAST)g_IMEShareProc.FSupportSty)(uSty, uStyAltered); } typedef IMESHAREAPI const IMESTYLE * (IMECDECL*PISFA_CAST)(const UINT); const IMESTYLE * CW32System::PIMEStyleFromAttr ( const UINT uAttr) { if (g_IMEShareProc.PIMEStyleFromAttr == NULL) SetIMEProcAddr( g_IMEShareProc.PIMEStyleFromAttr, DLL_IMESHARE, "PIMEStyleFromAttr" ); return ((PISFA_CAST)g_IMEShareProc.PIMEStyleFromAttr)( uAttr ); } typedef IMESHAREAPI const IMECOLORSTY * (IMECDECL*PCSTFIS_CAST)(const IMESTYLE *); const IMECOLORSTY * CW32System::PColorStyleTextFromIMEStyle ( const IMESTYLE * pIMEStyle) { if (g_IMEShareProc.PColorStyleTextFromIMEStyle == NULL) SetIMEProcAddr( g_IMEShareProc.PColorStyleTextFromIMEStyle, DLL_IMESHARE, "PColorStyleTextFromIMEStyle" ); return ((PCSTFIS_CAST)g_IMEShareProc.PColorStyleTextFromIMEStyle)( pIMEStyle ); } typedef IMESHAREAPI const IMECOLORSTY * (IMECDECL*PCSBFIS_CAST)(const IMESTYLE *); const IMECOLORSTY * CW32System::PColorStyleBackFromIMEStyle ( const IMESTYLE * pIMEStyle) { if (g_IMEShareProc.PColorStyleBackFromIMEStyle == NULL) SetIMEProcAddr( g_IMEShareProc.PColorStyleBackFromIMEStyle, DLL_IMESHARE, "PColorStyleBackFromIMEStyle" ); return ((PCSBFIS_CAST)g_IMEShareProc.PColorStyleBackFromIMEStyle)( pIMEStyle ); } typedef IMESHAREAPI BOOL (IMECDECL*FBIS_CAST)(const IMESTYLE *); BOOL CW32System::FBoldIMEStyle ( const IMESTYLE * pIMEStyle) { if (g_IMEShareProc.FBoldIMEStyle == NULL) SetIMEProcAddr( g_IMEShareProc.FBoldIMEStyle, DLL_IMESHARE, "FBoldIMEStyle" ); return ((FBIS_CAST)g_IMEShareProc.FBoldIMEStyle)( pIMEStyle ); } typedef IMESHAREAPI BOOL (IMECDECL*FIIS_CAST)(const IMESTYLE * ); BOOL CW32System::FItalicIMEStyle ( const IMESTYLE * pIMEStyle) { if (g_IMEShareProc.FItalicIMEStyle == NULL) SetIMEProcAddr( g_IMEShareProc.FItalicIMEStyle, DLL_IMESHARE, "FItalicIMEStyle" ); return ((FIIS_CAST)g_IMEShareProc.FItalicIMEStyle)( pIMEStyle ); } typedef IMESHAREAPI BOOL (IMECDECL*FUIS_CAST)(const IMESTYLE *); BOOL CW32System::FUlIMEStyle ( const IMESTYLE * pIMEStyle) { if (g_IMEShareProc.FUlIMEStyle == NULL) SetIMEProcAddr( g_IMEShareProc.FUlIMEStyle, DLL_IMESHARE, "FUlIMEStyle" ); return ((FUIS_CAST)g_IMEShareProc.FUlIMEStyle)( pIMEStyle ); } typedef IMESHAREAPI UINT (IMECDECL*IUIS_CAST)(const IMESTYLE *); UINT CW32System::IdUlIMEStyle ( const IMESTYLE * pIMEStyle) { if (g_IMEShareProc.IdUlIMEStyle == NULL) SetIMEProcAddr( g_IMEShareProc.IdUlIMEStyle, DLL_IMESHARE, "IdUlIMEStyle" ); return ((IUIS_CAST)g_IMEShareProc.IdUlIMEStyle)( pIMEStyle );; } typedef IMESHAREAPI COLORREF (IMECDECL*RFICS_CAST)(const IMECOLORSTY *); COLORREF CW32System::RGBFromIMEColorStyle ( const IMECOLORSTY * pColorStyle ) { if (g_IMEShareProc.RGBFromIMEColorStyle == NULL) SetIMEProcAddr( g_IMEShareProc.RGBFromIMEColorStyle, DLL_IMESHARE, "RGBFromIMEColorStyle" ); return ((RFICS_CAST)g_IMEShareProc.RGBFromIMEColorStyle)( pColorStyle ); } CONVERTMODE WINAPI CW32System::DetermineConvertMode( HDC hdc, BYTE tmCharSet ) { CONVERTMODE cm = CVT_NONE; // Some fonts have problems under Win95 with the GetCharWidthW call; this // is a simple heuristic to determine if this problem exists. if (OnWin9x()) { INT widthA, widthW; BOOL fResA, fResW; // FE font on Non-FE Win95 cannot use // GetCharWidthW and ExtTextOutW if(IsFECharSet(tmCharSet) && OnWin95FE()) // always use ANSI call for DBC fonts. cm = CVT_WCTMB; else { fResA = GetCharWidthA( hdc, ' ', ' ', &widthA ); fResW = GetCharWidthW( hdc, L' ', L' ', &widthW ); if ( fResA && fResW && widthA != widthW ) cm = CVT_WCTMB; else { fResA = GetCharWidthA( hdc, 'a', 'a', &widthA ); fResW = GetCharWidthW( hdc, L'a', L'a', &widthW ); if ( fResA && fResW && widthA != widthW ) cm = CVT_WCTMB; } } } return cm; } void WINAPI CW32System::CalcUnderlineInfo(HDC hdc, CCcs *pcccs, TEXTMETRIC *ptm ) { OUTLINETEXTMETRICA *potm; unsigned cb; CTempBuf tb; if (ptm->tmPitchAndFamily & TMPF_TRUETYPE) { cb = GetOutlineTextMetricsA(hdc, 0, NULL); if ((cb != 0) && ((potm = (OUTLINETEXTMETRICA *) tb.GetBuf(cb)) != NULL) && GetOutlineTextMetricsA(hdc, cb, potm)) { pcccs->_dyULOffset = -potm->otmsUnderscorePosition; pcccs->_dyULWidth = (short) max(1, potm->otmsUnderscoreSize); pcccs->_dySOOffset = -potm->otmsStrikeoutPosition; pcccs->_dySOWidth = (short) max(1, (int)potm->otmsStrikeoutSize); return; } } // Default calculation of size of underline SHORT dyDescent = pcccs->_yDescent; if (0 == dyDescent) { dyDescent = pcccs->_yHeight >> 3; } pcccs->_dyULWidth = (short) max(1, dyDescent / 4); pcccs->_dyULOffset = (dyDescent - 3 * pcccs->_dyULWidth + 1) / 2; if ((0 == pcccs->_dyULOffset) && (dyDescent > 1)) { pcccs->_dyULOffset = 1; } pcccs->_dySOOffset = -ptm->tmAscent / 3; pcccs->_dySOWidth = pcccs->_dyULWidth; return; } BOOL WINAPI CW32System::ShowScrollBar( HWND hWnd, int wBar, BOOL bShow, LONG ) { return ::ShowScrollBar( hWnd, wBar, bShow ); } BOOL WINAPI CW32System::EnableScrollBar( HWND hWnd, UINT wSBflags, UINT wArrows ) { return ::EnableScrollBar( hWnd, wSBflags, wArrows ); } /* * ReExtTextOutW(uiCodePage, hdc, x, y, fuOptions, lprc, lpString, cch ,lpDx, uiCodePage) * * @mfunc * Patch around the Win95 FE bug and MetaFile problem. * * @rdesc * Returns whatever ExtTextOut returns */ BOOL ReExtTextOutW( HDC hdc, //@parm handle to device context int xp, //@parm x-coordinate of reference point int yp, //@parm y-coordinate of reference point UINT fuOptions, //@parm text-output options CONST RECT *lprect, //@parm optional clipping and/or opaquing rectangle const WCHAR *lpwchString, //@parm points to string UINT cchCount, //@parm number of characters in string CONST INT *lpDx, //@parm Ptr to array of intercharacter spacing values UINT uiCodePage) //@parm CodePage for converting to Ansi { // This is a portion of Word code adapted for our needs. // This is a work around for Win95FE bugs that cause GPFs in GDI if multiple // characters above Unicode 0x7F are passed to ExtTextOutW. // Also, when uiCodePage is non-zero, we want to output all characters using // ExtTextOutA - each character at a time. Assert(lpDx); int cch; const WCHAR *lpwchT = lpwchString; const WCHAR *lpwchStart = lpwchT; const WCHAR *lpwchEnd = lpwchString + cchCount; CONST int *lpdxpCur; BOOL fRet = 0; while (lpwchT < lpwchEnd) { // characters less than 0x007F do not need special treatment // we output then in contiguous runs if (*lpwchT > 0x007F || uiCodePage) { if ((cch = lpwchT - lpwchStart) > 0) { lpdxpCur = lpDx + (lpwchStart - lpwchString); // Output the run of chars less than 0x7F fRet = ExtTextOutW(hdc, xp, yp, fuOptions, lprect, lpwchStart, cch, lpdxpCur); if (!fRet) return fRet; fuOptions &= ~ETO_OPAQUE; // Don't erase mutliple times!!! // Advance while (cch--) xp += *lpdxpCur++; lpwchStart = lpwchT; } // Output chars above 0x7F one at a time to prevent Win95 FE GPF lpdxpCur = lpDx + (lpwchStart - lpwchString); if (uiCodePage) { // Need to convert to Ansi and use ExtTextOutA char chAnsi[2]; int cbConv = WideCharToMultiByte(uiCodePage, 0, lpwchStart, 1, chAnsi, 2, NULL, NULL); if (cbConv <= 0) { chAnsi[0] = '?'; cbConv = 1; } fRet = ExtTextOutA(hdc, xp, yp, fuOptions, lprect, chAnsi, cbConv, lpdxpCur); } else fRet = ExtTextOutW(hdc, xp, yp, fuOptions, lprect, lpwchStart, 1, lpdxpCur); if (!fRet) return fRet; fuOptions &= ~ETO_OPAQUE; // Don't erase multiple times!!! // Advance if (lpdxpCur) xp += *lpdxpCur; lpwchStart++; } lpwchT++; } // output the final run; also, if we were called with cchCount == 0, // make a call here to erase the rectangle if ((cch = lpwchT - lpwchStart) > 0 || !cchCount) fRet = ExtTextOutW(hdc, xp, yp, fuOptions, lprect, lpwchStart, cch, lpDx + (lpwchStart - lpwchString)); return fRet; } void WINAPI CW32System::REExtTextOut( CONVERTMODE cm, UINT uiCodePage, HDC hdc, int x, int y, UINT fuOptions, CONST RECT *lprc, const WCHAR *lpString, UINT cch, CONST INT *lpDx, BOOL FEFontOnNonFEWin9x ) { bool fConvert = false; BOOL fForceGdiFont = FALSE; HFONT hfont = NULL, hfontCur = NULL; // In order to get the EURO character to print, we need to force the // printer to use the glyphs inside GDI if(lpString[0] == EURO && (GetDeviceCaps(hdc, TECHNOLOGY) != DT_RASDISPLAY || W32->IsEnhancedMetafileDC(hdc))) { fForceGdiFont = TRUE; hfontCur = SelectFont(hdc, GetStockObject(ANSI_VAR_FONT)); LOGFONT lf; GetObject(hfontCur, sizeof(LOGFONT), &lf); lf.lfOutPrecision = OnWin9x() ? OUT_TT_ONLY_PRECIS : OUT_SCREEN_OUTLINE_PRECIS; hfont = CreateFontIndirect(&lf); SelectObject(hdc, hfont); } if(OnWin9x()) { // To get around some Win95 printer device problems with ExtTextOutW, // use ExtTextOutA if string is ASCII or if it's 1252 and any // nonASCII chars are between 0xA0 and 0xFF. for(UINT i = 0; i < cch && (lpString[i] <= 0x7F || IN_RANGE(0xA0, lpString[i], 0xFF) && uiCodePage == 1252); i++) ; if(i == cch) // All ASCII or ANSI: setup to truncate { // to low byte and use ExtTextOutA cm = CVT_LOWBYTE; fConvert = true; } } if (fConvert || !FEFontOnNonFEWin9x && cm != CVT_NONE) { if (cm == CVT_WCTMB) { if (IsFECodePage(uiCodePage)) { if (OnWinNTNonFE() || (OnWin9x() && !OnWin95())) { // On NonFE NT4 and Win98, we need to textout each char using // ExtTextOutA ReExtTextOutW(hdc, x, y, fuOptions, lprc, lpString, cch, lpDx, uiCodePage); goto LExit; } } } // Need to convert and use ExtTextOutA CTempCharBuf tcb; CTempBuf tDx; // Double the buffer size int cbString = (cm == CVT_LOWBYTE) ? cch : cch * 2; // String buffer for converted string - allocate on the stack char *psz = tcb.GetBuf(cbString); INT *pTempDx = NULL; if (NULL == psz) { // Could not allocate buffer goto LExit; } int cbConv = 0; if(cm == CVT_WCTMB) { cbConv = WideCharToMultiByte(uiCodePage, 0, lpString, cch, psz, cbString, NULL, NULL); if(!cbConv) { // The conversion failed for one reason or another. We should // make every effort to use WCTMB before we fall back to // taking the low-byte of every wchar (below), otherwise we // risk dropping the high-bytes and displaying garbage. // Use the cpg from the font, since the uiCodePage passed is // the requested codepage and the font-mapper may very well // have mapped to a different one. TEXTMETRIC tm; uiCodePage = (GetTextMetrics(hdc, &tm) && tm.tmCharSet != DEFAULT_CHARSET && (UINT)GetCodePage(tm.tmCharSet) != uiCodePage) ? GetCodePage(tm.tmCharSet) : 1252; cbConv = WideCharToMultiByte(uiCodePage, 0, lpString, cch, psz, cbString, NULL, NULL); } if (cbConv > 0 && lpDx) { pTempDx = (INT *)tDx.GetBuf(cbConv * sizeof(INT)); if (pTempDx) { // Repack lpDx to handle DBC INT *pDx = pTempDx; CONST INT*pInputDx = lpDx; char *pTempChar = psz; INT cNumBytes = cbConv; while (cNumBytes > 0) { cNumBytes--; if (GetTrailBytesCount(*pTempChar++, uiCodePage)) { *pDx++ = *pInputDx++; *pDx++ = 0; cNumBytes--; pTempChar++; } else *pDx++ = *pInputDx++; } } } } else { Assert(cm == CVT_LOWBYTE); // drop through and convert using only low-bytes of WCHAR's } // WCTMB failed OR cm == CVT_LOWBYTE if(!cbConv) // Convert WCHARs to CHARs { // FUTURE: We come here for both SYMBOL_CHARSET fonts and for // DBCS bytes stuffed into wchar's (one byte per wchar) when // the requested code page is not installed on the machine and // the MBTWC fails. Instead, we could have another conversion // mode that collects each DBCS char as a single wchar and then // remaps to a DBCS string for ExtTextOutA. This would allow us // to display text if the system has the right font even tho it // doesn't have the right cpg. // If we are converting this WCHAR buffer in this manner // (by taking only the low-byte's of the WCHAR's), it is // because: // 1) cm == CVT_LOWBYTE // 2) WCTMB above failed for some reason or another. It may // be the case that the string is entirely ASCII in which // case dropping the high-bytes is not a big deal (otherwise // we assert). cbConv = cch; while(cch--) { #ifdef DEBUG if (uiCodePage != CP_SYMBOL && lpString[cch] > 0xFF) Tracef(TRCSEVWARN, "Non-zero high-byte WCHAR: %x", lpString[cch]); #endif psz[cch] = lpString[cch]; } } ::ExtTextOutA(hdc, x, y, fuOptions, lprc, psz, cbConv, pTempDx ? pTempDx : lpDx); goto LExit; } if (OnWin9xFE() || FEFontOnNonFEWin9x) ReExtTextOutW(hdc, x, y, fuOptions, lprc, lpString, cch, lpDx, 0); else ::ExtTextOutW(hdc, x, y, fuOptions, lprc, lpString, cch, lpDx); LExit: if (fForceGdiFont) { SelectObject(hdc, hfontCur); SideAssert(DeleteObject(hfont)); } } void WINAPI CW32System::REGetCharWidth( HDC hdc, WCHAR ch, SHORT * pWidth, UINT cpg, SHORT xOverhang, INT iDefWidth) { BOOL fForceGdiFont = FALSE; HFONT hfont = NULL, hfontCur = NULL; int iwidth; *pWidth = 0; if ((cpg == CP_SYMBOL || ch <= 127) && ::GetCharWidthA(hdc, ch, ch, &iwidth)) { *pWidth = (SHORT)iwidth; goto Done; } if(ch == EURO && (GetDeviceCaps(hdc, TECHNOLOGY) != DT_RASDISPLAY || W32->IsEnhancedMetafileDC(hdc))) { fForceGdiFont = TRUE; hfontCur = SelectFont(hdc, GetStockObject(ANSI_VAR_FONT)); LOGFONT lf; GetObject(hfontCur, sizeof(LOGFONT), &lf); lf.lfOutPrecision = OnWin9x() ? OUT_TT_ONLY_PRECIS : OUT_SCREEN_OUTLINE_PRECIS; hfont = CreateFontIndirect(&lf); SelectObject(hdc, hfont); } // For most workarounds, we will use the workarounds on all the OSs. // We only use specific workaround is MBTWC conversion is needed. // This is a workaround for Win95 FE bugs // FUTURE (keithcu) This logic could be simplified. if (OnWin95() && !IN_RANGE(0x80, ch, 0xFF) && // Not high ANSI? (cpg == CP_CHINESE_TRAD || cpg == CP_CHINESE_SIM)) // Chinese CodePage? { int numOfDBCS = 0; ::GetCharWidthW(hdc, 0x4e00, 0x4e00, &iwidth); *pWidth = (SHORT)iwidth; if (IN_RANGE(0x4e00, ch, 0x9fff)) goto Done; // Use WCTMB heuristic char ansiChar[2]; BOOL bDefCharUsed = FALSE; numOfDBCS = ::WideCharToMultiByte( cpg, 0, &ch, 1, ansiChar, 2, NULL, &bDefCharUsed); WORD wDBCS = (BYTE)ansiChar[0]; if (2 == numOfDBCS) wDBCS = (BYTE)ansiChar[0] << 8 | (BYTE)ansiChar[1]; if (numOfDBCS > 0 && ::GetCharWidthA( hdc, wDBCS, wDBCS, &iwidth)) { *pWidth = (SHORT)iwidth; goto Done; } } //Win '95 GPFs if you pass in 0xFFFF if (ch == 0xFFFF) ch = 0xFFFE; if (::GetCharWidthW(hdc, ch, ch, &iwidth)) *pWidth = (SHORT)iwidth; if(fForceGdiFont) { SelectObject(hdc, hfontCur); SideAssert(DeleteObject(hfont)); } Done: *pWidth -= xOverhang; if (0 >= *pWidth) { // Sometimes GetCharWidth will return a zero length for small // characters. When this happens we will use the default width // for the font if that is non-zero otherwise we just us 1 because // this is the smallest valid value. // This code can also be triggered if the overhang is bigger than the // width returned by the OS call to get the character width. if (0 == iDefWidth) *pWidth = 1; else *pWidth = (SHORT)iDefWidth; } } BOOL WINAPI CW32System::IsEnhancedMetafileDC( HDC hDC ) { BOOL fEMFDC = FALSE; DWORD dwObjectType; dwObjectType = ::GetObjectType( hDC ); if ( OBJ_ENHMETADC == dwObjectType || OBJ_ENHMETAFILE == dwObjectType ) fEMFDC = TRUE; else if ( OnWin95() && OBJ_DC == dwObjectType ) { // HACK Alert, Enhanced Metafile DC does not support any Escape function // and shoudl return 0. int iEscapeFuction = QUERYESCSUPPORT; if ( Escape( hDC, QUERYESCSUPPORT, sizeof(int), (LPCSTR)&iEscapeFuction, NULL) == 0 ) fEMFDC = TRUE; } return fEMFDC; } HPALETTE WINAPI CW32System::ManagePalette( HDC hdc, CONST LOGPALETTE *plogpal, HPALETTE &hpalOld, HPALETTE &hpalNew ) { if (hpalNew == NULL) { hpalNew = ::CreatePalette(plogpal); if (hpalNew != NULL) { hpalOld = ::SelectPalette(hdc, hpalNew, TRUE); ::RealizePalette(hdc); } } else { // A new palette was created previously and we are restoring the old one ::SelectPalette(hdc, hpalOld, TRUE); ::RealizePalette(hdc); DeleteObject(hpalNew); hpalNew = NULL; } return hpalNew; } int WINAPI CW32System::GetMapMode(HDC hdc) { return ::GetMapMode(hdc); } BOOL WINAPI CW32System::WinLPtoDP(HDC hdc, LPPOINT lppoints, int nCount) { return ::LPtoDP(hdc, lppoints, nCount); } long WINAPI CW32System::WvsprintfA( LONG cbBuf, LPSTR szBuf, LPCSTR szFmt, va_list arglist ) { LONG cb; cb = ::wvsprintfA( szBuf, szFmt, arglist ); Assert(cb < cbBuf); return cb; } int WINAPI CW32System::MulDiv(int nNumber, int nNumerator, int nDenominator) { if ((nNumerator && nNumerator == nDenominator) || (nDenominator && !nNumber)) return nNumber; return ::MulDiv(nNumber, nNumerator, nDenominator); } /* * GetFacePriorityCharSet(WCHAR* szFaceName) * * @func * return charset *really* supported by given facename */ int CALLBACK GetFacePriCharSetProc ( ENUMLOGFONTEX *lpelfe, NEWTEXTMETRIC *lpntm, int iFontType, LPARAM lParam) { Assert (lParam); *(BYTE*)lParam = lpntm->tmCharSet; return 0; } void CW32System::GetFacePriCharSet(HDC hdc, LOGFONT* plf) { ::EnumFontFamiliesEx(hdc, plf, (FONTENUMPROC)GetFacePriCharSetProc, (LPARAM)&plf->lfCharSet, 0); } /* * CW32System::ReadRegDigitSubstitionMode(void) * * @mfunc * Get the digit substitution mode (available on BiDi/Thai platforms) * * @rdesc * 0 - Context (digit shape follows preceding run or CHARFORMAT's charset * 1 - None (digits always show as European digit shape) * 2 - National (digits always show as user locale's native shape) */ BYTE CW32System::ReadRegDigitSubstitutionMode() { HKEY hk; DWORD keyDataType; DWORD dwDataSize; BYTE rgbValue[2]; BYTE bDigitMode; bDigitMode = DIGITS_NOTIMPL; // assume "Not Implemented" // Perform platform check before reading registry if (!OnWin9xFE() && !OnWinNTFE() && IsComplexScriptLcid(GetThreadLocale())) { if(RegOpenKeyExA(HKEY_CURRENT_USER, "Control Panel\\International", 0, // reserved KEY_QUERY_VALUE, &hk) == ERROR_SUCCESS) { dwDataSize = 2; if (RegQueryValueExA(hk, "NumShape", NULL, // reserved &keyDataType, (LPBYTE) &rgbValue, &dwDataSize) == ERROR_SUCCESS) { if (rgbValue[0] > 0x2f) bDigitMode = rgbValue[0] - 0x30 + 1; if (bDigitMode > DIGITS_NATIONAL) bDigitMode = DIGITS_NONE; } RegCloseKey(hk); } } return bDigitMode; } #ifdef DEBUG /* * TestGetCharFlags125x(iFirst, iLast) * * @func * Unit test function for GetCharFlags125x(). Assert if GetCharFlags125x() * claims that any char in Unicode range iFirst thru iLast 1) should * roundtrip multibyte conversion using a codepage in the range 1250-1258 * when it doesn't, or 2) shouldn't roundtrip when it does. */ BOOL TestGetCharFlags125x( int iFirst, int iLast) { LONG cch = iLast - iFirst + 1; LONG i; Assert(cch <= 0x700 - 0xA0); char rgach[0x700 - 0xA0]; WCHAR rgch [0x700 - 0xA0]; WCHAR * pch; for(i = iFirst, pch = rgch; i <= iLast; pch++, i++) *pch = (WCHAR)i; for(int CodePage = 1250; CodePage <= 1258; CodePage++) { if(cch != WideCharToMultiByte(CodePage, 0, rgch, cch, rgach, cch, "\0", NULL) || cch != MultiByteToWideChar(CodePage, 0, rgach, cch, rgch, cch)) { continue; // Missing code page } // 1250 1251 1252 1253 1254 1255 1256 1257 1258 const static WORD rgMask[] = {0x2, 0x4, 0x1, 0x8, 0x10, 0x20, 0x40, 0x80, 0x100}; DWORD dwMask = rgMask[CodePage - 1250] << 8; for(i = iFirst, pch = rgch; i <= iLast; pch++, i++) { AssertSz(!((*pch != (WCHAR)i) ^ !(W32->GetCharFlags125x(i) & dwMask)), "GetCharFlags125x() failure"); *pch = (WCHAR)i; // Restore value } } return TRUE; // Above AssertSz() reports any errors } #endif /* * CW32System::InitSysParams(fUpdate) * * @mfunc * This method is used to initialize certain system wide parameters that * that are used in richedit. This can also be used as an update method * if we ever handle system parameter change notifications. The update * parameter id provided for this purpose. Also note that if we ever support * SysParam updating, we may have to protect access with locks. */ void CW32System::InitSysParams(BOOL fUpdate) { TRACEBEGIN(TRCSUBSYSUTIL, TRCSCOPEINTERN, "CW32System::InitSysParams"); CLock lock; if (!_fSysParamsOk || fUpdate) { _fSysParamsOk = TRUE; const LONG dxSelBarDefaultSize = 8; HDC hdc = GetScreenDC(); HFONT hfontOld; TEXTMETRIC tm; _xPerInchScreenDC = GetDeviceCaps(hdc, LOGPIXELSX); if (_xPerInchScreenDC == 0) _xPerInchScreenDC = 0x60; _yPerInchScreenDC = GetDeviceCaps(hdc, LOGPIXELSY); if (_yPerInchScreenDC == 0) _yPerInchScreenDC = 0x60; int cPalette = GetDeviceCaps(hdc, SIZEPALETTE); // 256 colors is where we seem to need to use the palette. if (256 == cPalette) { _fUsePalette = TRUE; } // calculate a himetric selection bar for the window's host. _dxSelBar = W32->DXtoHimetricX(dxSelBarDefaultSize, _xPerInchScreenDC); RefreshKeyboardLayout(); _hSystemFont = (HFONT)GetStockObject(SYSTEM_FONT); hfontOld = SelectFont(hdc, _hSystemFont); if(hfontOld) { W32->GetTextMetrics(hdc, &tm); _xWidthSys = (INT) tm.tmAveCharWidth; _yHeightSys = (INT) tm.tmHeight; _ySysFontLeading = (INT) tm.tmInternalLeading; _bSysCharSet = tm.tmCharSet; SelectFont(hdc, hfontOld); } _nScrollInset = (WORD)GetProfileIntA("windows", "ScrollInset", DD_DEFSCROLLINSET); _nDragDelay = (WORD)GetProfileIntA("windows", "DragDelay", DD_DEFDRAGDELAY); _nDragMinDist = (WORD)GetProfileIntA("windows", "DragMinDist", DD_DEFDRAGMINDIST); _nScrollDelay = (WORD)GetProfileIntA("windows", "ScrollDelay", DD_DEFSCROLLDELAY); _nScrollInterval = (WORD)GetProfileIntA("windows", "ScrollInterval", DD_DEFSCROLLINTERVAL); _nScrollVAmount = (WORD)(GetYPerInchScreenDC()*DEFSCROLLVAMOUNT)/100; _nScrollHAmount = (GetXPerInchScreenDC()*DEFSCROLLHAMOUNT)/100; _cxBorder = GetSystemMetrics(SM_CXBORDER); // Unsizable window border _cyBorder = GetSystemMetrics(SM_CYBORDER); // widths _cxVScroll = GetSystemMetrics(SM_CXVSCROLL); // dimensions _cyHScroll = GetSystemMetrics(SM_CYHSCROLL); // _cxDoubleClk = GetSystemMetrics(SM_CXDOUBLECLK); _cyDoubleClk = GetSystemMetrics(SM_CYDOUBLECLK); _DCT = GetDoubleClickTime(); _sysiniflags = ::GetProfileIntA("richedit30", "flags", 0); #ifdef DEBUG if(OnWinNT5() && (_sysiniflags & SYSINI_DEBUGGCF125X)) { TestGetCharFlags125x(0xA0, 0x6FF); TestGetCharFlags125x(0x2000, 0x2122); } #endif _bDigitSubstMode = ReadRegDigitSubstitutionMode(); if (g_pusp) g_pusp->ApplyDigitSubstitution(_bDigitSubstMode); } } /* * CW32System::GetSizeCursor(void) * * @mfunc * Get the sizing cursor (double arrow) specified by * the resource id. If the cursors are not loaded * load them and cache them. * parameters: * idcur - cursor resource id. * * @rdesc * Handle to cursor or null if failure. Returns NULL if * idcur is null. */ HCURSOR CW32System::GetSizeCursor( LPTSTR idcur) { if(!idcur ) return NULL; //If any cursor isn't loaded, try loading it. if(!_hcurSizeNS) _hcurSizeNS = LoadCursor(NULL, IDC_SIZENS); if(!_hcurSizeWE) _hcurSizeWE = LoadCursor(NULL, IDC_SIZEWE); if(!_hcurSizeNWSE) _hcurSizeNWSE = LoadCursor(NULL, IDC_SIZENWSE); if(!_hcurSizeNESW) _hcurSizeNESW = LoadCursor(NULL, IDC_SIZENESW); //Return cursor corresponding to id passed in. if(idcur == IDC_SIZENS && _hcurSizeNS) return _hcurSizeNS; if(idcur == IDC_SIZEWE && _hcurSizeWE) return _hcurSizeWE; if(idcur == IDC_SIZENWSE && _hcurSizeNWSE) return _hcurSizeNWSE; if(idcur == IDC_SIZENESW && _hcurSizeNESW) return _hcurSizeNESW; AssertSz(FALSE, "Failure loading sizing cursor."); return NULL; } /* * CW32System:GetRollerLineScrollCount() * * @mfunc returns the number of lines to scroll with a roller mouse wheel. * -1 means scroll by pages * * @devnote We have to do different things for different platforms; NT4.0 has * built in support for this functionality. */ /* excerpt from new winuser.h for calls to SystemParametersInfo */ #ifndef SPI_GETWHEELSCROLLLINES #define SPI_GETWHEELSCROLLLINES 104 #endif LONG CW32System::GetRollerLineScrollCount() { if( _cLineScroll == 0 ) { #ifndef _WIN64 HKEY hdlKey; DWORD keyDataType; CHAR charData[128]; DWORD dwDataBufSize; // Fall back Value _cLineScroll = 0; // Read registry directly for Windows 95 & WinNT3.51, if WinNT 4.0 // and above then use SystemParametersInfo if((OnWin95()) || (_dwPlatformId == VER_PLATFORM_WIN32_NT) && (_dwMajorVersion < 4)) { // Read registry directly if ( RegOpenKeyExA(HKEY_CURRENT_USER, "Control Panel\\Desktop", 0, KEY_QUERY_VALUE, &hdlKey) == ERROR_SUCCESS ) { dwDataBufSize = sizeof(charData); if ( RegQueryValueExA(hdlKey, "WheelScrollLines", NULL, // reserved &keyDataType, (LPBYTE) &charData, &dwDataBufSize) == ERROR_SUCCESS ) { _cLineScroll = W32->strtoul( charData ); //String representation } } else { // We didn't find line scroll count in the registery. Check for a Mouse // Wheel window and query the window how many lines to scroll static UINT idWheelSupport = RegisterWindowMessageA(MSH_WHEELSUPPORT); static UINT idScrollLine = RegisterWindowMessageA(MSH_SCROLL_LINES); HWND hwndMsWheel = FindWindowA(MSH_WHEELMODULE_CLASS, MSH_WHEELMODULE_TITLE); if (hwndMsWheel && SendMessageA(hwndMsWheel, idWheelSupport, 0, 0)) _cLineScroll = SendMessageA(hwndMsWheel, idScrollLine, 0, 0); } RegCloseKey(hdlKey); } else if ( (_dwPlatformId == VER_PLATFORM_WIN32_NT) && (_dwMajorVersion >= 4) || OnWin9x()) #endif //_WIN64 { //call this function if on NT4 or Win98 (NOTE: it isn't sufficient to use //OnWin9x() to determine if we are on a win98 system but since the //previous if stmt checks to see if we are in a win95 system OnWin9x //can be use) SystemParametersInfoA(SPI_GETWHEELSCROLLLINES, 0, &_cLineScroll, 0); } } return _cLineScroll; } //+--------------------------------------------------------------------------- // // Member: CStrIn::CStrIn // // Synopsis: Inits the class. // // NOTE: Don't inline these functions or you'll increase code size // by pushing -1 on the stack for each call. // //---------------------------------------------------------------------------- CStrIn::CStrIn(LPCWSTR pwstr, UINT CodePage) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrIn::CStrIn"); Init(pwstr, -1, CodePage); } CStrIn::CStrIn(LPCWSTR pwstr, int cwch, UINT CodePage) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrIn::CStrIn"); Init(pwstr, cwch, CodePage); } //+--------------------------------------------------------------------------- // // Member: CStrIn::Init // // Synopsis: Converts a LPWSTR function argument to a LPSTR. // // Arguments: [pwstr] -- The function argument. May be NULL or an atom // (HIWORD(pwstr) == 0). // // [cwch] -- The number of characters in the string to // convert. If -1, the string is assumed to be // NULL terminated and its length is calculated. // // Modifies: [this] // //---------------------------------------------------------------------------- void CStrIn::Init( LPCWSTR pwstr, int cwch, UINT CodePage) //@parm Code page to use (CP_ACP is default) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrIn::Init"); int cchBufReq; _cchLen = 0; // Check if string is NULL or an atom. if (HIWORD((DWORD_PTR)pwstr) == 0) { _pstr = (LPSTR) pwstr; return; } Assert(cwch == -1 || cwch > 0); // // Convert string to preallocated buffer, and return if successful. // _cchLen = W32->MbcsFromUnicode(_ach, ARRAY_SIZE(_ach), pwstr, cwch, CodePage); if (_cchLen > 0) { if(_ach[_cchLen-1] == 0) _cchLen--; // account for terminator _pstr = _ach; return; } // // Alloc space on heap for buffer. // TRACEINFOSZ("CStrIn: Allocating buffer for wrapped function argument."); cchBufReq = WideCharToMultiByte( CP_ACP, 0, pwstr, cwch, NULL, 0, NULL, NULL); Assert(cchBufReq > 0); _pstr = new char[cchBufReq]; if (!_pstr) { // On failure, the argument will point to the empty string. TRACEINFOSZ("CStrIn: No heap space for wrapped function argument."); _ach[0] = 0; _pstr = _ach; return; } Assert(HIWORD((DWORD_PTR)_pstr)); _cchLen = -1 + W32->MbcsFromUnicode(_pstr, cchBufReq, pwstr, cwch); Assert(_cchLen >= 0); } //+--------------------------------------------------------------------------- // // Class: CStrInMulti (CStrIn) // // Purpose: Converts multiple strings which are terminated by two NULLs, // e.g. "Foo\0Bar\0\0" // //---------------------------------------------------------------------------- class CStrInMulti : public CStrIn { public: CStrInMulti(LPCWSTR pwstr, UINT CodePage); }; //+--------------------------------------------------------------------------- // // Member: CStrInMulti::CStrInMulti // // Synopsis: Converts mulitple LPWSTRs to a multiple LPSTRs. // // Arguments: [pwstr] -- The strings to convert. // // Modifies: [this] // //---------------------------------------------------------------------------- CStrInMulti::CStrInMulti( LPCWSTR pwstr, UINT CodePage) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrInMulti::CStrInMulti"); LPCWSTR pwstrT; // We don't handle atoms because we don't need to. Assert(HIWORD((DWORD_PTR)pwstr)); // // Count number of characters to convert. // pwstrT = pwstr; if (pwstr) { do { while (*pwstrT++) ; } while (*pwstrT++); } Init(pwstr, pwstrT - pwstr, CodePage); } //+--------------------------------------------------------------------------- // // Member: CStrOut::CStrOut // // Synopsis: Allocates enough space for an out buffer. // // Arguments: [pwstr] -- The Unicode buffer to convert to when destroyed. // May be NULL. // // [cwchBuf] -- The size of the buffer in characters. // // Modifies: [this]. // //---------------------------------------------------------------------------- CStrOut::CStrOut(LPWSTR pwstr, int cwchBuf) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrOut::CStrOut"); Assert(cwchBuf >= 0); _pwstr = pwstr; _cwchBuf = cwchBuf; if (!pwstr) { Assert(cwchBuf == 0); _pstr = NULL; return; } Assert(HIWORD((DWORD_PTR)pwstr)); // Initialize buffer in case Windows API returns an error. _ach[0] = 0; // Use preallocated buffer if big enough. if (cwchBuf * 2 <= ARRAY_SIZE(_ach)) { _pstr = _ach; return; } // Allocate buffer. TRACEINFOSZ("CStrOut: Allocating buffer for wrapped function argument."); _pstr = new char[cwchBuf * 2]; if (!_pstr) { // // On failure, the argument will point to a zero-sized buffer initialized // to the empty string. This should cause the Windows API to fail. // TRACEINFOSZ("CStrOut: No heap space for wrapped function argument."); Assert(cwchBuf > 0); _pwstr[0] = 0; _cwchBuf = 0; _pstr = _ach; return; } Assert(HIWORD((DWORD_PTR)_pstr)); _pstr[0] = 0; } //+--------------------------------------------------------------------------- // // Member: CStrOut::Convert // // Synopsis: Converts the buffer from MBCS to Unicode. // //---------------------------------------------------------------------------- int CStrOut::Convert() { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrOut::Convert"); int cch; if (!_pstr) return 0; cch = MultiByteToWideChar(CP_ACP, 0, _pstr, -1, _pwstr, _cwchBuf); Assert(cch > 0 || _cwchBuf == 0); Free(); if (cch > 0 && cch <= _cwchBuf && _pwstr[cch-1] == L'\0') cch--; return cch; } //+--------------------------------------------------------------------------- // // Member: CStrOut::~CStrOut // // Synopsis: Converts the buffer from MBCS to Unicode. // // Note: Don't inline this function, or you'll increase code size as // both Convert() and CConvertStr::~CConvertStr will be called // inline. // //---------------------------------------------------------------------------- CStrOut::~CStrOut() { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrOut::~CStrOut"); Convert(); } // // MultiByte --> UNICODE routins // //+--------------------------------------------------------------------------- // // Member: CConvertStr::Free // // Synopsis: Frees string if alloc'd and initializes to NULL. // //---------------------------------------------------------------------------- void CConvertStr::Free() { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CConvertStr::Free"); if (_pstr != _ach && HIWORD((DWORD_PTR)_pstr) != 0) { delete [] _pstr; } _pstr = NULL; } //+--------------------------------------------------------------------------- // // Member: CConvertStrW::Free // // Synopsis: Frees string if alloc'd and initializes to NULL. // //---------------------------------------------------------------------------- void CConvertStrW::Free() { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CConvertStrW::Free"); if (_pwstr != _awch && HIWORD((DWORD_PTR)_pwstr) != 0 ) { delete [] _pwstr; } _pwstr = NULL; } //+--------------------------------------------------------------------------- // // Member: CStrInW::CStrInW // // Synopsis: Inits the class. // // NOTE: Don't inline these functions or you'll increase code size // by pushing -1 on the stack for each call. // //---------------------------------------------------------------------------- CStrInW::CStrInW(LPCSTR pstr) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrInW::CStrInW"); Init(pstr, -1, CP_ACP); } CStrInW::CStrInW(LPCSTR pstr, UINT uiCodePage) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrInW::CStrInW"); Init(pstr, -1, uiCodePage); } CStrInW::CStrInW(LPCSTR pstr, int cch, UINT uiCodePage) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrInW::CStrInW"); Init(pstr, cch, uiCodePage); } //+--------------------------------------------------------------------------- // // Member: CStrInW::Init // // Synopsis: Converts a LPSTR function argument to a LPWSTR. // // Arguments: [pstr] -- The function argument. May be NULL or an atom // (HIWORD(pwstr) == 0). // // [cch] -- The number of characters in the string to // convert. If -1, the string is assumed to be // NULL terminated and its length is calculated. // // Modifies: [this] // //---------------------------------------------------------------------------- void CStrInW::Init(LPCSTR pstr, int cch, UINT uiCodePage) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrInW::Init"); int cchBufReq; _cwchLen = 0; // Check if string is NULL or an atom. if (HIWORD((DWORD_PTR)pstr) == 0) { _pwstr = (LPWSTR) pstr; return; } Assert(cch == -1 || cch > 0); // // Convert string to preallocated buffer, and return if successful. // _cwchLen = MultiByteToWideChar( uiCodePage, 0, pstr, cch, _awch, ARRAY_SIZE(_awch)); if (_cwchLen > 0) { if(_awch[_cwchLen-1] == 0) _cwchLen--; // account for terminator _pwstr = _awch; return; } // // Alloc space on heap for buffer. // TRACEINFOSZ("CStrInW: Allocating buffer for wrapped function argument."); cchBufReq = MultiByteToWideChar( CP_ACP, 0, pstr, cch, NULL, 0); Assert(cchBufReq > 0); _pwstr = new WCHAR[cchBufReq]; if (!_pwstr) { // On failure, the argument will point to the empty string. TRACEINFOSZ("CStrInW: No heap space for wrapped function argument."); _awch[0] = 0; _pwstr = _awch; return; } Assert(HIWORD((DWORD_PTR)_pwstr)); _cwchLen = -1 + MultiByteToWideChar( uiCodePage, 0, pstr, cch, _pwstr, cchBufReq); Assert(_cwchLen >= 0); } //+--------------------------------------------------------------------------- // // Member: CStrOutW::CStrOutW // // Synopsis: Allocates enough space for an out buffer. // // Arguments: [pstr] -- The ansi buffer to convert to when destroyed. // May be NULL. // // [cchBuf] -- The size of the buffer in characters. // // Modifies: [this]. // //---------------------------------------------------------------------------- CStrOutW::CStrOutW(LPSTR pstr, int cchBuf, UINT uiCodePage) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrOutW::CStrOutW"); Assert(cchBuf >= 0); _pstr = pstr; _cchBuf = cchBuf; _uiCodePage = uiCodePage; if (!pstr) { Assert(cchBuf == 0); _pwstr = NULL; return; } Assert(HIWORD((DWORD_PTR)pstr)); // Initialize buffer in case Windows API returns an error. _awch[0] = 0; // Use preallocated buffer if big enough. if (cchBuf <= ARRAY_SIZE(_awch)) { _pwstr = _awch; return; } // Allocate buffer. TRACEINFOSZ("CStrOutW: Allocating buffer for wrapped function argument."); _pwstr = new WCHAR[cchBuf * 2]; if (!_pwstr) { // // On failure, the argument will point to a zero-sized buffer initialized // to the empty string. This should cause the Windows API to fail. // TRACEINFOSZ("CStrOutW: No heap space for wrapped function argument."); Assert(cchBuf > 0); _pstr[0] = 0; _cchBuf = 0; _pwstr = _awch; return; } Assert(HIWORD((DWORD_PTR)_pwstr)); _pwstr[0] = 0; } //+--------------------------------------------------------------------------- // // Member: CStrOutW::Convert // // Synopsis: Converts the buffer from Unicode to MBCS // //---------------------------------------------------------------------------- int CStrOutW::Convert() { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrOutW::Convert"); int cch; if (!_pwstr) return 0; int cchBuf = _cchBuf; cch = W32->MbcsFromUnicode(_pstr, cchBuf, _pwstr, -1, _uiCodePage); Free(); if (cch > 0 && cch <= _cchBuf && _pstr[cch-1] == '\0') cch--; return cch; } //+--------------------------------------------------------------------------- // // Member: CStrOutW::~CStrOutW // // Synopsis: Converts the buffer from Unicode to MBCS. // // Note: Don't inline this function, or you'll increase code size as // both Convert() and CConvertStr::~CConvertStr will be called // inline. // //---------------------------------------------------------------------------- CStrOutW::~CStrOutW() { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CStrOutW::~CStrOutW"); Convert(); } BOOL CW32System::GetVersion( DWORD *pdwPlatformId, DWORD *pdwMajorVersion, DWORD *pdwMinorVersion ) { OSVERSIONINFOA osv; osv.dwOSVersionInfoSize = sizeof(OSVERSIONINFOA); *pdwPlatformId = 0; *pdwMajorVersion = 0; if (::GetVersionExA(&osv)) { *pdwPlatformId = osv.dwPlatformId; *pdwMajorVersion = osv.dwMajorVersion; *pdwMinorVersion = osv.dwMinorVersion; return TRUE; } return FALSE; } BOOL CW32System::GetStringTypes( LCID lcid, LPCTSTR lpSrcStr, int cchSrc, LPWORD lpCharType1, LPWORD lpCharType3) { if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) { if(::GetStringTypeExW(lcid, CT_CTYPE1, lpSrcStr, cchSrc, lpCharType1)) return ::GetStringTypeExW(lcid, CT_CTYPE3, lpSrcStr, cchSrc, lpCharType3); return FALSE; } CStrIn str(lpSrcStr, cchSrc, ConvertLanguageIDtoCodePage(lcid)); LONG cch = str.strlen(); if(::GetStringTypeExA(lcid, CT_CTYPE1, str, cch, lpCharType1)) return ::GetStringTypeExA(lcid, CT_CTYPE3, str, cch, lpCharType3); return FALSE; } BOOL WINAPI CW32System::GetStringTypeEx( LCID lcid, DWORD dwInfoType, LPCTSTR lpSrcStr, int cchSrc, LPWORD lpCharType ) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "GetStringTypeEx"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::GetStringTypeExW(lcid, dwInfoType, lpSrcStr, cchSrc, lpCharType); CStrIn str(lpSrcStr, cchSrc); return GetStringTypeExA(lcid, dwInfoType, str, str.strlen(), lpCharType); } typedef LPSTR (CALLBACK *FnCharChangeCase)(LPSTR); static LPWSTR CharChangeCase(LPWSTR pwstr, FnCharChangeCase pfn) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CharChangeCaseWrap"); if (HIWORD((DWORD_PTR)pwstr) == 0) { LPSTR pstr=0; int retCode; char DBChar[3]; retCode = W32->MbcsFromUnicode((LPSTR) &pstr, sizeof(pstr), (LPWSTR) &pwstr, 1); Assert(HIWORD((DWORD_PTR)pstr) == 0); if (retCode == 2) { // This is a DBC, use string DWORD iTemp = (DWORD)((DWORD_PTR)pstr); DBChar[0] = char(iTemp & 0x0ff); DBChar[1] = char(iTemp >> 8); DBChar[2] = 0; pstr = (*pfn)(DBChar); W32->UnicodeFromMbcs((LPWSTR) &pwstr, sizeof(pwstr) / sizeof(WCHAR), (LPSTR)DBChar, 2); } else { pstr = (*pfn)(pstr); W32->UnicodeFromMbcs((LPWSTR) &pwstr, sizeof(pwstr) / sizeof(WCHAR), (LPSTR) &pstr); } Assert(HIWORD((DWORD_PTR)pwstr) == 0); } else { CStrOut strOut(pwstr, W32->wcslen(pwstr)); W32->MbcsFromUnicode(strOut, strOut.BufSize(), pwstr); (*pfn)(strOut); } return pwstr; } LPWSTR WINAPI CW32System::CharLower(LPWSTR pwstr) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CharLower"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::CharLowerW(pwstr); return CharChangeCase(pwstr, CharLowerA); } DWORD WINAPI CW32System::CharLowerBuff(LPWSTR pwstr, DWORD cchLength) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CharLowerBuff"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::CharLowerBuffW(pwstr, cchLength); LPWSTR lpBuffer = pwstr; for (DWORD pos = 0; pos < cchLength; pos++, lpBuffer++) *lpBuffer = (WCHAR)CharChangeCase((LPWSTR)*lpBuffer, CharLowerA); return pos; } DWORD WINAPI CW32System::CharUpperBuff(LPWSTR pwstr, DWORD cchLength) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CharUpperBuff"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::CharUpperBuffW(pwstr, cchLength); LPWSTR lpBuffer = pwstr; for (DWORD pos = 0; pos < cchLength; pos++, lpBuffer++) *lpBuffer = (WCHAR)CharChangeCase((LPWSTR)*lpBuffer, CharUpperA); return pos; } typedef HDC (CALLBACK *FnCreateHDCA)(LPCSTR, LPCSTR, LPCSTR, CONST DEVMODEA *); static HDC WINAPI CreateHDCAux( LPCWSTR lpszDriver, LPCWSTR lpszDevice, LPCWSTR lpszOutput, CONST DEVMODEW * lpInitData, FnCreateHDCA pfn ) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CreateHDCWrap"); DEVMODEA devmode; CStrIn strDriver(lpszDriver); CStrIn strDevice(lpszDevice); CStrIn strOutput(lpszOutput); if ( lpInitData ) { // converting DEVMODEW to DEVMODEA int byteCount; // copying the data between the two strings members byteCount = (char *)&(devmode.dmFormName) - (char *)&(devmode.dmSpecVersion); memcpy(&(devmode.dmSpecVersion), &(lpInitData->dmSpecVersion), byteCount); // copying the data after the second string member byteCount = (char *)((char *)&devmode + sizeof(DEVMODEA)) - (char *)&(devmode.dmLogPixels); memcpy(&(devmode.dmLogPixels), &(lpInitData->dmLogPixels), byteCount); // converting the two strings members W32->MbcsFromUnicode((CHAR *)devmode.dmDeviceName, CCHDEVICENAME, lpInitData->dmDeviceName); W32->MbcsFromUnicode((CHAR *)devmode.dmFormName, CCHFORMNAME, lpInitData->dmFormName); } return (*pfn)(strDriver, strDevice, strOutput, lpInitData ? &devmode : NULL); } HDC WINAPI CW32System::CreateIC( LPCWSTR lpszDriver, LPCWSTR lpszDevice, LPCWSTR lpszOutput, CONST DEVMODEW * lpInitData) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CreateIC"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::CreateICW( lpszDriver, lpszDevice, lpszOutput, lpInitData ); return CreateHDCAux(lpszDriver, lpszDevice, lpszOutput, lpInitData, CreateICA); } HANDLE WINAPI CW32System::CreateFile( LPCWSTR lpFileName, DWORD dwDesiredAccess, DWORD dwShareMode, LPSECURITY_ATTRIBUTES lpSecurityAttributes, DWORD dwCreationDisposition, DWORD dwFlagsAndAttributes, HANDLE hTemplateFile ) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CreateFile"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::CreateFileW(lpFileName, dwDesiredAccess, dwShareMode, lpSecurityAttributes, dwCreationDisposition, dwFlagsAndAttributes, hTemplateFile); CStrIn str(lpFileName); return ::CreateFileA( str, dwDesiredAccess, dwShareMode, lpSecurityAttributes, dwCreationDisposition, dwFlagsAndAttributes, hTemplateFile); } HFONT WINAPI CW32System::CreateFontIndirect(CONST LOGFONTW * plfw) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CreateFontIndirect"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::CreateFontIndirectW(plfw); LOGFONTA lfa; HFONT hFont; memcpy(&lfa, plfw, offsetof(LOGFONTA, lfFaceName)); MbcsFromUnicode(lfa.lfFaceName, ARRAY_SIZE(lfa.lfFaceName), plfw->lfFaceName, -1, CP_ACP, UN_NOOBJECTS); hFont = ::CreateFontIndirectA(&lfa); return hFont; } int WINAPI CW32System::CompareString ( LCID Locale, // locale identifier DWORD dwCmpFlags, // comparison-style options LPCWSTR lpString1, // pointer to first string int cch1, // size, in bytes or characters, of first string LPCWSTR lpString2, // pointer to second string int cch2 // size, in bytes or characters, of second string ) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "CompareString"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::CompareStringW(Locale, dwCmpFlags, lpString1, cch1, lpString2, cch2); CStrIn str1(lpString1, cch1); CStrIn str2(lpString2, cch2); return CompareStringA( Locale, dwCmpFlags, str1, str1.strlen(), str2, str2.strlen() ); } LRESULT WINAPI CW32System::DefWindowProc(HWND hWnd, UINT msg, WPARAM wParam, LPARAM lParam) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "DefWindowProcWrap"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::DefWindowProcW(hWnd, msg, wParam, lParam); return ::DefWindowProcA(hWnd, msg, wParam, lParam); } int WINAPI CW32System::GetObject(HGDIOBJ hgdiObj, int cbBuffer, LPVOID lpvObj) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "GetObject"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::GetObjectW( hgdiObj, cbBuffer, lpvObj); int nRet; if(cbBuffer != sizeof(LOGFONTW) || !lpvObj) { nRet = ::GetObjectA(hgdiObj, cbBuffer, lpvObj); if(nRet == sizeof(LOGFONTA)) { nRet = sizeof(LOGFONTW); } } else { LOGFONTA lfa; nRet = ::GetObjectA(hgdiObj, sizeof(lfa), &lfa); if(nRet > 0) { memcpy(lpvObj, &lfa, offsetof(LOGFONTW, lfFaceName)); UnicodeFromMbcs(((LOGFONTW*)lpvObj)->lfFaceName, ARRAY_SIZE(((LOGFONTW*)lpvObj)->lfFaceName), lfa.lfFaceName, -1); nRet = sizeof(LOGFONTW); } } return nRet; } DWORD APIENTRY CW32System::GetProfileSection( LPCWSTR lpAppName, LPWSTR lpReturnedString, DWORD nSize ) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "GetProfileSection"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::GetProfileSectionW( lpAppName, lpReturnedString, nSize ); CStrIn strAppName(lpAppName); // we can't use CStrOut here, since the returned string contains a set of // strings delimited by single-NULL's and terminated by a double-NULL char *pszReturnedString; pszReturnedString = new char[nSize]; Assert(pszReturnedString); DWORD cch = ::GetProfileSectionA(strAppName, pszReturnedString, nSize); if(cch) { cch = MultiByteToWideChar(CP_ACP, 0, pszReturnedString, cch, lpReturnedString, nSize); } delete pszReturnedString; return cch; } BOOL APIENTRY CW32System::GetTextExtentPoint32( HDC hdc, LPCWSTR pwsz, int cb, LPSIZE pSize ) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "GetTextExtentPoint32"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::GetTextExtentPoint32W( hdc, pwsz, cb, pSize ); CStrIn str(pwsz); return ::GetTextExtentPoint32A(hdc, str, cb, pSize); } int WINAPI CW32System::GetTextFace( HDC hdc, int cch, LPWSTR lpFaceName ) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "GetTextFace"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::GetTextFaceW( hdc, cch, lpFaceName ); CStrOut str(lpFaceName, cch); ::GetTextFaceA(hdc, str.BufSize(), str); return str.Convert(); } BOOL WINAPI CW32System::GetTextMetrics(HDC hdc, LPTEXTMETRICW lptm) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "GetTextMetrics"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::GetTextMetricsW( hdc, lptm); BOOL ret; TEXTMETRICA tm; ret = ::GetTextMetricsA(hdc, &tm); if (ret) { lptm->tmHeight = tm.tmHeight; lptm->tmAscent = tm.tmAscent; lptm->tmDescent = tm.tmDescent; lptm->tmInternalLeading = tm.tmInternalLeading; lptm->tmExternalLeading = tm.tmExternalLeading; lptm->tmAveCharWidth = tm.tmAveCharWidth; lptm->tmMaxCharWidth = tm.tmMaxCharWidth; lptm->tmWeight = tm.tmWeight; lptm->tmOverhang = tm.tmOverhang; lptm->tmDigitizedAspectX = tm.tmDigitizedAspectX; lptm->tmDigitizedAspectY = tm.tmDigitizedAspectY; lptm->tmItalic = tm.tmItalic; lptm->tmUnderlined = tm.tmUnderlined; lptm->tmStruckOut = tm.tmStruckOut; lptm->tmPitchAndFamily = tm.tmPitchAndFamily; lptm->tmCharSet = tm.tmCharSet; UnicodeFromMbcs(&lptm->tmFirstChar, 1, (LPSTR) &tm.tmFirstChar, 1); UnicodeFromMbcs(&lptm->tmLastChar, 1, (LPSTR) &tm.tmLastChar, 1); UnicodeFromMbcs(&lptm->tmDefaultChar, 1, (LPSTR) &tm.tmDefaultChar, 1); UnicodeFromMbcs(&lptm->tmBreakChar, 1, (LPSTR) &tm.tmBreakChar, 1); } return ret; } LONG WINAPI CW32System::GetWindowLong(HWND hWnd, int nIndex) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "GetWindowLong"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::GetWindowLongW(hWnd, nIndex); return ::GetWindowLongA(hWnd, nIndex); } LONG_PTR WINAPI CW32System::GetWindowLongPtr(HWND hWnd, int nIndex) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "GetWindowLongPtr"); #ifdef _WIN64 return GetWindowLongPtrW(hWnd, nIndex); #else return GetWindowLong(hWnd, nIndex); #endif } DWORD WINAPI CW32System::GetClassLong(HWND hWnd, int nIndex) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "GetClassLong"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::GetClassLongW(hWnd, nIndex); return ::GetClassLongA(hWnd, nIndex); } HBITMAP WINAPI CW32System::LoadBitmap(HINSTANCE hInstance, LPCWSTR lpBitmapName) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "LoadBitmap"); Assert(HIWORD((DWORD_PTR)lpBitmapName) == 0); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::LoadBitmapW(hInstance, lpBitmapName); return ::LoadBitmapA(hInstance, (LPCSTR) lpBitmapName); } HCURSOR WINAPI CW32System::LoadCursor(HINSTANCE hInstance, LPCWSTR lpCursorName) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "LoadCursor"); Assert(HIWORD((DWORD_PTR)lpCursorName) == 0); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::LoadCursorW(hInstance, lpCursorName); return ::LoadCursorA(hInstance, (LPCSTR) lpCursorName); } HINSTANCE WINAPI CW32System::LoadLibrary(LPCWSTR lpLibFileName) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "LoadLibrary"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::LoadLibraryW(lpLibFileName); CStrIn str(lpLibFileName); return ::LoadLibraryA(str); } LRESULT WINAPI CW32System::SendMessage( HWND hWnd, UINT Msg, WPARAM wParam, LPARAM lParam ) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "SendMessage"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId && ::IsWindowUnicode(hWnd)) return ::SendMessageW(hWnd, Msg, wParam, lParam); // We never need Ansi to Unicode translation in our use of SendMessage // Our list boxes always use Unicode. switch (Msg) { // We don't want to translate these! // case LB_ADDSTRING: // case LB_INSERTSTRING: // case CB_ADDSTRING: // case CB_SELECTSTRING: // case CB_INSERTSTRING: // case LB_GETTEXT: // case CB_GETLBTEXT: case WM_GETTEXT: { CStrOut str((LPWSTR)lParam, (int)wParam); ::SendMessageA(hWnd, Msg, str.BufSize(), (LPARAM)(LPSTR)str); return str.Convert(); } break; case WM_SETTEXT: case EM_REPLACESEL: Assert(FALSE); // We never send these. Dead code? break; case EM_SETPASSWORDCHAR: Assert(FALSE); // We never send these. Dead code? break; } return ::SendMessageA(hWnd, Msg, wParam, lParam); } LONG WINAPI CW32System::SetWindowLong(HWND hWnd, int nIndex, LONG dwNewLong) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "SetWindowLong"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::SetWindowLongW(hWnd, nIndex, dwNewLong); return ::SetWindowLongA(hWnd, nIndex, dwNewLong); } LONG WINAPI CW32System::SetWindowLongPtr(HWND hWnd, int nIndex, LONG_PTR dwNewLong) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "SetWindowLongPtr"); #ifdef _WIN64 return ::SetWindowLongPtrW(hWnd, nIndex, dwNewLong); #else return SetWindowLong(hWnd, nIndex, dwNewLong); #endif } BOOL WINAPI CW32System::PostMessage( HWND hWnd, UINT Msg, WPARAM wParam, LPARAM lParam ) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "PostMessage"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::PostMessageW(hWnd, Msg, wParam, lParam); return ::PostMessageA(hWnd, Msg, wParam, lParam); } BOOL WINAPI CW32System::UnregisterClass(LPCWSTR lpClassName, HINSTANCE hInstance) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "UnregisterClass"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::UnregisterClassW( lpClassName, hInstance); CStrIn str(lpClassName); return ::UnregisterClassA(str, hInstance); } int WINAPI CW32System::lstrcmp(LPCWSTR lpString1, LPCWSTR lpString2) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "lstrcmp"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::lstrcmpW(lpString1, lpString2); return W32->wcscmp(lpString1, lpString2); } int WINAPI CW32System::lstrcmpi(LPCWSTR lpString1, LPCWSTR lpString2) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "lstrcmpi"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::lstrcmpiW(lpString1, lpString2); // Fall back on the simple minded CRT algortihm // The CRT actually has two paths. This is the simple one const wchar_t * dst = lpString1; const wchar_t * src = lpString2; wchar_t f,l; do { f = ((*dst <= L'Z') && (*dst >= L'A')) ? *dst + L'a' - L'A' : *dst; l = ((*src <= L'Z') && (*src >= L'A')) ? *src + L'a' - L'A' : *src; dst++; src++; } while ( (f) && (f == l) ); return (int)(f - l); } BOOL WINAPI CW32System::PeekMessage( LPMSG lpMsg, HWND hWnd, UINT wMsgFilterMin, UINT wMsgFilterMax, UINT wRemoveMsg ) { TRACEBEGIN(TRCSUBSYSWRAP, TRCSCOPEINTERN, "PeekMessage"); if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::PeekMessageW(lpMsg, hWnd, wMsgFilterMin, wMsgFilterMax, wRemoveMsg); return ::PeekMessageA(lpMsg, hWnd, wMsgFilterMin, wMsgFilterMax, wRemoveMsg); } DWORD WINAPI CW32System::GetModuleFileName( HMODULE hModule, LPWSTR lpFilename, DWORD nSize ) { if (VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId) return ::GetModuleFileNameW(hModule, lpFilename, nSize); CStrOut strout(lpFilename, nSize); DWORD res = ::GetModuleFileNameA(hModule, strout, nSize); strout.Convert(); return res; } // The high bits of _yHeightUI & _yHeightOther are being used to check if // font is installed in the system #define NEED_TO_CHECK_FONT 0x080 struct PreferredFontInfo { BYTE _bPitchAndFamilyUI; BYTE _yHeightUI; SHORT _iFontUI; BYTE _bPitchAndFamilyOther; BYTE _yHeightOther; SHORT _iFontOther; }; PreferredFontInfo g_pfinfo[NCHARSETS]; void CW32System::InitPreferredFontInfo() { // For UI case, we will use Word9 UI fonts // For Non-UI case, we will use Word9 default email fonts short iFont; UINT uSysDefCodePage = GetSystemDefaultCodePage(); // Japanese Init static const WCHAR lpUIJapanFontName[] = L"MS UI Gothic"; static const WCHAR lpOthJapanFontName[] = {0xFF2D,0xFF33,0x0020,0xFF30,0x30B4,0x30B7,0x30C3,0x30AF, 0}; static const WCHAR lpOthJapanFontNameEUC[] = L"MS PGothic"; iFont = GetFontNameIndex( lpUIJapanFontName ); SetPreferredFontInfo( CP_JAPAN, true, iFont, 9 | NEED_TO_CHECK_FONT, 17 ); if (uSysDefCodePage == CP_JAPAN) iFont = GetFontNameIndex( lpOthJapanFontName ); else iFont = GetFontNameIndex( lpOthJapanFontNameEUC ); SetPreferredFontInfo( CP_JAPAN, false, iFont, 10 | NEED_TO_CHECK_FONT, 17 ); // Korean Init static const WCHAR lpUIKoreanFontName[] = {0xAD74, 0xB9BC, 0}; static const WCHAR lpUIKoreanFontNameEUC[] = L"Gulim"; if (uSysDefCodePage == CP_KOREAN) iFont = GetFontNameIndex( lpUIKoreanFontName ); else iFont = GetFontNameIndex( lpUIKoreanFontNameEUC ); SetPreferredFontInfo( CP_KOREAN, true, iFont, 9 | NEED_TO_CHECK_FONT, 49 ); SetPreferredFontInfo( CP_KOREAN, false, iFont, 9 | NEED_TO_CHECK_FONT, 49 ); // Traditional Chinese Init static const WCHAR lpUITChineseFontName[] = {0x65B0, 0x7D30, 0x660E, 0x9AD4, 0}; static const WCHAR lpUITChineseFontNameEUC[] = L"PMingLiU"; iFont = GetFontNameIndex(uSysDefCodePage == CP_CHINESE_TRAD ? lpUITChineseFontName : lpUITChineseFontNameEUC); SetPreferredFontInfo( CP_CHINESE_TRAD, true, iFont, 9 | NEED_TO_CHECK_FONT, 54 ); SetPreferredFontInfo( CP_CHINESE_TRAD, false, iFont, 9 | NEED_TO_CHECK_FONT, 54 ); // Simplified Chinese Init static const WCHAR lpUISChineseFontName[] = {0x5B8B, 0x4F53, 0}; static const WCHAR lpUISChineseFontNameEUC[] = L"SimSun"; iFont = GetFontNameIndex(uSysDefCodePage == CP_CHINESE_SIM ? lpUISChineseFontName : lpUISChineseFontNameEUC); SetPreferredFontInfo( CP_CHINESE_SIM, true, iFont, 9 | NEED_TO_CHECK_FONT, 54 ); SetPreferredFontInfo( CP_CHINESE_SIM, false, iFont, 10 | NEED_TO_CHECK_FONT, 54 ); // English Init iFont = GetFontNameIndex( szTahoma ); SetPreferredFontInfo(1252, true, iFont, 8, DEFAULT_PITCH | FF_SWISS ); iFont = GetFontNameIndex( szArial ); SetPreferredFontInfo(1252, false, iFont, 10, DEFAULT_PITCH | FF_SWISS ); // SYMBOL_CHARSET iFont = GetFontNameIndex( szWingdings ); SetPreferredFontInfo(CP_SYMBOL, true, iFont, 8, DEFAULT_PITCH | FF_DONTCARE); SetPreferredFontInfo(CP_SYMBOL, false, iFont, 10, DEFAULT_PITCH | FF_DONTCARE); // Vietnamese Init iFont = GetFontNameIndex( szTahoma ); SetPreferredFontInfo(1258, true, iFont, 8, DEFAULT_PITCH | FF_SWISS ); iFont = GetFontNameIndex( szArial ); SetPreferredFontInfo(1258, false, iFont, 10, DEFAULT_PITCH | FF_SWISS ); // Thai Init if (OnWinNT5()) iFont = GetFontNameIndex( szMicrosSansSerif ); else iFont = GetFontNameIndex( szTahoma ); SetPreferredFontInfo(874, true, iFont, 8, DEFAULT_PITCH | FF_SWISS ); iFont = GetFontNameIndex( szCordiaNew ); SetPreferredFontInfo(874, false, iFont, 14, DEFAULT_PITCH | FF_SWISS ); // Devanagari Init iFont = GetFontNameIndex( szMangal ); SetPreferredFontInfo(CP_DEVANAGARI, true, iFont, 8, DEFAULT_PITCH | FF_SWISS ); SetPreferredFontInfo(CP_DEVANAGARI, false, iFont, 10, DEFAULT_PITCH | FF_SWISS ); // Tamil Init iFont = GetFontNameIndex( szLatha ); SetPreferredFontInfo(CP_TAMIL, true, iFont, 8, DEFAULT_PITCH | FF_SWISS ); SetPreferredFontInfo(CP_TAMIL, false, iFont, 10, DEFAULT_PITCH | FF_SWISS ); // Georgian and Armenian Init if(OnWinNT5()) { iFont = GetFontNameIndex(szArialUnicode); SetPreferredFontInfo(CP_GEORGIAN, true, iFont, 8, DEFAULT_PITCH | FF_SWISS); SetPreferredFontInfo(CP_GEORGIAN, false, iFont, 10, DEFAULT_PITCH | FF_SWISS); SetPreferredFontInfo(CP_ARMENIAN, true, iFont, 8, DEFAULT_PITCH | FF_SWISS); SetPreferredFontInfo(CP_ARMENIAN, false, iFont, 10, DEFAULT_PITCH | FF_SWISS); } _fFEFontInfo = FEDATA_NOT_INIT; // Check installed keyboard layouts CheckInstalledKeyboards(); } void CW32System::CheckInstalledKeyboards() { HKL rghkl[MAX_HKLS]; INT cLayouts = ::GetKeyboardLayoutList(MAX_HKLS, rghkl); LONG cpg; INT iScript; for(INT i = 0; i < cLayouts; i++) { cpg = ConvertLanguageIDtoCodePage(PRIMARYLANGID(rghkl[i])); GetCharSet(cpg, &iScript); // Get script index if(iScript >= 0) SetPreferredKbd(iScript, rghkl[i]); } } bool CW32System::SetPreferredFontInfo( int cpg, bool fUIFont, SHORT iFont, BYTE yHeight, BYTE bPitchAndFamily ) { int iPFI; CLock lock; GetCharSet( cpg, &iPFI ); if (iPFI == -1) return false; if (fUIFont) { g_pfinfo[iPFI]._bPitchAndFamilyUI = bPitchAndFamily; g_pfinfo[iPFI]._yHeightUI = yHeight; g_pfinfo[iPFI]._iFontUI = iFont; } else { g_pfinfo[iPFI]._bPitchAndFamilyOther = bPitchAndFamily; g_pfinfo[iPFI]._yHeightOther = yHeight; g_pfinfo[iPFI]._iFontOther = iFont; } SetFontLegitimateSize(iFont, fUIFont, yHeight & ~NEED_TO_CHECK_FONT, cpg); return true; } bool CW32System::GetPreferredFontInfo( int cpg, bool fUIFont, SHORT& iFont, BYTE& yHeight, BYTE& bPitchAndFamily ) { int iPFI; if (GetCharSet( cpg, &iPFI ) && (iPFI == -1)) return false; if (g_pfinfo[iPFI]._iFontUI == 0) { /* No entry. Try default */ iPFI = 0; } if (fUIFont) { bPitchAndFamily = g_pfinfo[iPFI]._bPitchAndFamilyUI; yHeight = g_pfinfo[iPFI]._yHeightUI; iFont = g_pfinfo[iPFI]._iFontUI; } else { bPitchAndFamily = g_pfinfo[iPFI]._bPitchAndFamilyOther; yHeight = g_pfinfo[iPFI]._yHeightOther; iFont = g_pfinfo[iPFI]._iFontOther; } if (yHeight & NEED_TO_CHECK_FONT) { // Check if the preferred font is installed in the system. CLock lock; HDC hDC = GetScreenDC(); // Turn off the checkfont bit yHeight &= ~NEED_TO_CHECK_FONT; if (fUIFont) g_pfinfo[iPFI]._yHeightUI &= ~NEED_TO_CHECK_FONT; else g_pfinfo[iPFI]._yHeightOther &= ~NEED_TO_CHECK_FONT; if (hDC) { const short *pFontIndex = fUIFont ? &g_pfinfo[iPFI]._iFontUI : &g_pfinfo[iPFI]._iFontOther; if (IsFontAvail( hDC, cpg, fUIFont, (short *)pFontIndex)) iFont = *pFontIndex; } } return true; } /* * CW32System::GetPreferredFontHeight( * bool fUIFont, * BYTE bOrgCharSet, * BYTE bNewCharSet, * SHORT yOrgHeight) * * * @mfunc * called when we need the default font size when changing from one charset to another. * * @rdesc * The preferred default font size in TWIP if the Original height is same as the * original charset default font size. Otherwise, it will return the Original height. * */ SHORT CW32System::GetPreferredFontHeight( bool fUIFont, BYTE bOrgCharSet, BYTE bNewCharSet, SHORT yOrgHeight ) { BYTE yOrgPreferredHeight; LONG idxOrgFont = ScriptIndexFromCharSet(bOrgCharSet); LONG idxNewFont = ScriptIndexFromCharSet(bNewCharSet); // No entry, forget it if (idxOrgFont == -1 || idxNewFont == -1) return yOrgHeight; yOrgPreferredHeight = fUIFont ? g_pfinfo[idxOrgFont]._yHeightUI : g_pfinfo[idxOrgFont]._yHeightOther; // Get New Preferred Height if (yOrgPreferredHeight && yOrgPreferredHeight == yOrgHeight/TWIPS_PER_POINT) { BYTE yNewHeight = (fUIFont ? g_pfinfo[idxNewFont]._yHeightUI : g_pfinfo[idxNewFont]._yHeightOther); if (yNewHeight) return yNewHeight * TWIPS_PER_POINT; } return yOrgHeight; } /* * CW32System::CheckInstalledFEFonts() * * * @mfunc * called when building FE fonts installed and User default LCID info * * @devnote * This information is necessary when we want to classify Chinese characters * and Full-width characters. * */ void CW32System::CheckInstalledFEFonts() { UINT uUserCodepage; CLock cLock; HDC hDC = GetScreenDC(); _fFEFontInfo = 0; uUserCodepage = ConvertLanguageIDtoCodePage(::GetUserDefaultLCID()); if (!IsFECodePage(uUserCodepage)) uUserCodepage = GetACP(); switch (uUserCodepage) { case CP_JAPAN: _fFEFontInfo |= (FEUSER_LCID | FEUSER_CP_JPN | JPN_FONT_AVAILABLE); break; case CP_KOREAN: _fFEFontInfo |= (FEUSER_LCID | FEUSER_CP_KOR | KOR_FONT_AVAILABLE); break; case CP_CHINESE_TRAD: _fFEFontInfo |= (FEUSER_LCID | FEUSER_CP_BIG5 | BIG5_FONT_AVAILABLE); break; case CP_CHINESE_SIM: _fFEFontInfo |= (FEUSER_LCID | FEUSER_CP_GB | GB_FONT_AVAILABLE); break; } if (hDC) { if (!(_fFEFontInfo & JPN_FONT_AVAILABLE) && IsFontAvail(hDC, CP_JAPAN)) _fFEFontInfo |= JPN_FONT_AVAILABLE; if (!(_fFEFontInfo & KOR_FONT_AVAILABLE) && IsFontAvail(hDC, CP_KOREAN)) _fFEFontInfo |= KOR_FONT_AVAILABLE; if (!(_fFEFontInfo & BIG5_FONT_AVAILABLE) && IsFontAvail(hDC, CP_CHINESE_TRAD)) _fFEFontInfo |= BIG5_FONT_AVAILABLE; if (!(_fFEFontInfo & GB_FONT_AVAILABLE) && IsFontAvail(hDC, CP_CHINESE_SIM)) _fFEFontInfo |= GB_FONT_AVAILABLE; } } /* * CW32System::IsFEFontInSystem( cpg ) * * * @mfunc * check if there is any FE font installed for the given codepage * * @devnote * This information is necessary when we want to classify Chinese characters * and Full-width characters. * */ bool CW32System::IsFEFontInSystem(int cpg) { int fFontExist = 0; if (_fFEFontInfo == FEDATA_NOT_INIT) { CLock Lock; // Look for FE fonts in the system CheckInstalledFEFonts(); } // Check if font for the codepage is in the system switch (cpg) { case CP_JAPAN: fFontExist = _fFEFontInfo & JPN_FONT_AVAILABLE; break; case CP_KOREAN: fFontExist = _fFEFontInfo & KOR_FONT_AVAILABLE; break; case CP_CHINESE_TRAD: fFontExist = _fFEFontInfo & BIG5_FONT_AVAILABLE; break; case CP_CHINESE_SIM: fFontExist = _fFEFontInfo & GB_FONT_AVAILABLE; break; } return (fFontExist != 0); } /* * CW32System::IsFontAvail( HDC hDC, int cpg, bool fUIFont, short *piFontIndex ) * * * @mfunc * called when checking if a font (UI or non-UI) is installed for a given codepage * * @devnote * We will try to create the font and verify the charset of the font * actually created. If the fontname index is supplied, we will check * if the requested font is installed. If the name from GDI is different, * the GDI font index will be returned in piFontIndex. * * @rdesc * true if a font that supports the given codepage is available. */ bool CW32System::IsFontAvail( HDC hDC, //@parm Screen hDC int cpg, //@parm cpg bool fUIFont, //@parm UI font? short *piFontIndex) //@parm Font Name Index (default = NULL) { LOGFONTW lf; HFONT hfont; bool retCode = false; int iPFI; BYTE bCharSet; if ((bCharSet = GetCharSet(cpg, &iPFI)) && (iPFI == -1)) return false; ZeroMemory(&lf, sizeof(lf)); // We want GDI to find a font that will support this charset // Unspecified entries in LOGFONT will be either default or don't care. lf.lfCharSet = bCharSet; if (fUIFont) { lf.lfHeight = g_pfinfo[iPFI]._yHeightUI; lf.lfPitchAndFamily = g_pfinfo[iPFI]._bPitchAndFamilyUI; wcscpy(lf.lfFaceName, GetFontName((LONG)(g_pfinfo[iPFI]._iFontUI))); } else { lf.lfHeight = g_pfinfo[iPFI]._yHeightOther; lf.lfPitchAndFamily = g_pfinfo[iPFI]._bPitchAndFamilyOther; wcscpy(lf.lfFaceName, GetFontName((LONG)(g_pfinfo[iPFI]._iFontOther))); } hfont = CreateFontIndirect(&lf); if(hfont) { TEXTMETRIC tm; HFONT hfontOld = SelectFont(hDC, hfont); if (GetTextMetrics(hDC, &tm) && tm.tmCharSet == bCharSet) { retCode = true; if (piFontIndex) { const WCHAR *pszFontName = GetFontName(*piFontIndex); if (pszFontName) { WCHAR szNewFaceName[LF_FACESIZE]; // Check if GDI gives us the same font name szNewFaceName[0] = L'\0'; GetTextFace(hDC, LF_FACESIZE, szNewFaceName); if (szNewFaceName[0] && wcsicmp(pszFontName, szNewFaceName)) *piFontIndex = GetFontNameIndex(szNewFaceName); // Different name } } } SelectFont(hDC, hfontOld); DeleteObject(hfont); } return retCode; } /* * CW32System::GetFEFontInfo( void ) * * * @mfunc * called when classifying Chinese characters and Full-width characters * * @devnote * Chinese characters and Full-width characters can be in any * of the four FE codepages. We want to classfy them according to the * User default LCID and which FE fonts are installed in the system. * * @rdesc * Codepage for the character. */ UINT CW32System::GetFEFontInfo() { int iDefUserCodepage = -1; if (_fFEFontInfo == FEDATA_NOT_INIT) { CLock Lock; // Check if FE fonts are available in the system CheckInstalledFEFonts(); } if (_fFEFontInfo & FEUSER_LCID) iDefUserCodepage = (_fFEFontInfo & FEUSER_CODEPAGE); if (iDefUserCodepage == FEUSER_CP_BIG5) return CP_CHINESE_TRAD; if (iDefUserCodepage == FEUSER_CP_GB) return CP_CHINESE_SIM; if (iDefUserCodepage == FEUSER_CP_JPN) return CP_JAPAN; if (iDefUserCodepage == FEUSER_CP_KOR) return CP_KOREAN; // Check which font is available and return the corresponding codepage // We check for Simplified Chinese first since it contains more Chinese // characters than Traditional Chinese. if (_fFEFontInfo & GB_FONT_AVAILABLE) return CP_CHINESE_SIM; if (_fFEFontInfo & BIG5_FONT_AVAILABLE) return CP_CHINESE_TRAD; if (_fFEFontInfo & JPN_FONT_AVAILABLE) return CP_JAPAN; if (_fFEFontInfo & KOR_FONT_AVAILABLE) return CP_KOREAN; return CP_CHINESE_SIM; // Well, no FE font, tough luck. } /* * CW32System::IsDiacriticOrKashida(ch, wC3Type) * * @mfunc * Return TRUE if ch or wC3Type reveals that ch is a nonspacing * diacritic or a kashida. Because Win9x GetStringTypeExW isn't * implemented, we use range checks for Win9x. * * @rdesc * True if ch or wC3Type reveals that ch is a nonspacing diacritic */ BOOL CW32System::IsDiacriticOrKashida( WCHAR ch, //@parm On Win9x, check ranges for ch WORD wC3Type) //@parm On WinNT, use C3-type check { if(VER_PLATFORM_WIN32_WINDOWS != _dwPlatformId && wC3Type) return wC3Type & (C3_DIACRITIC | C3_NONSPACING | C3_VOWELMARK | C3_KASHIDA); if(!IN_RANGE(0x300, ch, 0xe50)) // Combining diacritics of interest return FALSE; // fall in this range return IN_RANGE(0x300, ch, 0x36F) || IsDiacritic(ch) || IsBiDiKashida(ch); } /* * CW32System::IsDiacritic(ch) * * @mfunc * Return TRUE if ch falls in BiDi, Thai, Devanagari or Tamil diacritic range. */ BOOL CW32System::IsDiacritic( WCHAR ch) { // BiDi if (IsBiDiDiacritic(ch)) return TRUE; // Thai if (IN_RANGE(0xe31, ch, 0xe4e)) return IN_RANGE(0x0e47, ch, 0x0e4e) || IN_RANGE(0x0e34, ch, 0x0e3a) || ch == 0x0e31; // Devanagari if (IN_RANGE(0x0902, ch, 0x0963)) return IN_RANGE(0x0941, ch, 0x0948) || IN_RANGE(0x0951, ch, 0x0954) || ch == 0x094d || IN_RANGE(0x0962, ch, 0x0963) || IN_RANGE(0x0901, ch, 0x0902) || ch == 0x093c; // Tamil if (IN_RANGE(0x0b82, ch, 0x0bcd)) return ch == 0x0bcd || ch == 0x0bc0 || ch == 0x0b82; return FALSE; }