/******************************************************************************* * SPHelper.h * *------------* * Description: * This is the header file for core helper functions implementation. *------------------------------------------------------------------------------- * Copyright (c) Microsoft Corporation. All rights reserved. *******************************************************************************/ #ifndef SPHelper_h #define SPHelper_h #include #ifndef _INC_MALLOC #include #endif #ifndef __sapi_h__ #include #endif #ifndef __sapiddk_h__ #include #endif #ifndef SPError_h #include #endif #ifndef _INC_LIMITS #include #endif #ifndef _INC_MMSYSTEM #include #endif #ifndef __comcat_h__ #include #endif #ifndef _INC_MMREG #include #endif #include //=== Constants ============================================================== #define sp_countof(x) ((sizeof(x) / sizeof(*(x)))) /*** CSpDynamicString helper class * */ class CSpDynamicString { public: WCHAR * m_psz; CSpDynamicString() { m_psz = NULL; } CSpDynamicString(ULONG cchReserve) { m_psz = (WCHAR *)::CoTaskMemAlloc(cchReserve * sizeof(WCHAR)); } WCHAR * operator=(const CSpDynamicString& src) { if (m_psz != src.m_psz) { ::CoTaskMemFree(m_psz); m_psz = src.Copy(); } return m_psz; } WCHAR * operator=(const WCHAR * pSrc) { Clear(); if (pSrc) { ULONG cbNeeded = (wcslen(pSrc) + 1) * sizeof(WCHAR); m_psz = (WCHAR *)::CoTaskMemAlloc(cbNeeded); if (m_psz) { memcpy(m_psz, pSrc, cbNeeded); } } return m_psz; } WCHAR * operator=(const char * pSrc) { Clear(); if (pSrc) { ULONG cbNeeded = (lstrlenA(pSrc) + 1) * sizeof(WCHAR); m_psz = (WCHAR *)::CoTaskMemAlloc(cbNeeded); if (m_psz) { ::MultiByteToWideChar(CP_ACP, 0, pSrc, -1, m_psz, cbNeeded/sizeof(WCHAR)); } } return m_psz; } WCHAR * operator=(REFGUID rguid) { Clear(); ::StringFromCLSID(rguid, &m_psz); return m_psz; } /*explicit*/ CSpDynamicString(const WCHAR * pSrc) { m_psz = NULL; operator=(pSrc); } /*explicit*/ CSpDynamicString(const char * pSrc) { m_psz = NULL; operator=(pSrc); } /*explicit*/ CSpDynamicString(const CSpDynamicString& src) { m_psz = src.Copy(); } /*explicit*/ CSpDynamicString(REFGUID rguid) { ::StringFromCLSID(rguid, &m_psz); } ~CSpDynamicString() { ::CoTaskMemFree(m_psz); } unsigned int Length() const { return (m_psz == NULL)? 0 : wcslen(m_psz); } operator WCHAR * () const { return m_psz; } //The assert on operator& usually indicates a bug. If this is really //what is needed, however, take the address of the m_psz member explicitly. WCHAR ** operator&() { return &m_psz; } WCHAR * Append(const WCHAR * pszSrc) { if (pszSrc) { ULONG lenSrc = wcslen(pszSrc); if (lenSrc) { ULONG lenMe = Length(); WCHAR *pszNew = (WCHAR *)::CoTaskMemAlloc((lenMe + lenSrc + 1) * sizeof(WCHAR)); if (pszNew) { if (m_psz) // Could append to an empty string so check... { if (lenMe) { memcpy(pszNew, m_psz, lenMe * sizeof(WCHAR)); } ::CoTaskMemFree(m_psz); } memcpy(pszNew + lenMe, pszSrc, (lenSrc + 1) * sizeof(WCHAR)); m_psz = pszNew; } else { } } } return m_psz; } WCHAR * Append(const WCHAR * pszSrc, const ULONG lenSrc) { if (pszSrc && lenSrc) { ULONG lenMe = Length(); WCHAR *pszNew = (WCHAR *)::CoTaskMemAlloc((lenMe + lenSrc + 1) * sizeof(WCHAR)); if (pszNew) { if (m_psz) // Could append to an empty string so check... { if (lenMe) { memcpy(pszNew, m_psz, lenMe * sizeof(WCHAR)); } ::CoTaskMemFree(m_psz); } memcpy(pszNew + lenMe, pszSrc, lenSrc * sizeof(WCHAR)); *(pszNew + lenMe + lenSrc) = L'\0'; m_psz = pszNew; } else { } } return m_psz; } WCHAR * Append2(const WCHAR * pszSrc1, const WCHAR * pszSrc2) { ULONG lenSrc1 = pszSrc1 ? wcslen(pszSrc1) : 0; ULONG lenSrc2 = pszSrc2 ? wcslen(pszSrc2) : 0; if (lenSrc1 || lenSrc2) { ULONG lenMe = Length(); WCHAR *pszNew = (WCHAR *)::CoTaskMemAlloc((lenMe + lenSrc1 + lenSrc2 + 1) * sizeof(WCHAR)); if (pszNew) { if (m_psz) // Could append to an empty string so check... { if (lenMe) { memcpy(pszNew, m_psz, lenMe * sizeof(WCHAR)); } ::CoTaskMemFree(m_psz); } // In both of these cases, we copy the trailing NULL so that we're sure it gets // there (if lenSrc2 is 0 then we better copy it from pszSrc1). if (lenSrc1) { memcpy(pszNew + lenMe, pszSrc1, (lenSrc1 + 1) * sizeof(WCHAR)); } if (lenSrc2) { memcpy(pszNew + lenMe + lenSrc1, pszSrc2, (lenSrc2 + 1) * sizeof(WCHAR)); } m_psz = pszNew; } else { } } return m_psz; } WCHAR * Copy() const { if (m_psz) { CSpDynamicString szNew(m_psz); return szNew.Detach(); } return NULL; } CHAR * CopyToChar() const { if (m_psz) { CHAR* psz; ULONG cbNeeded = ::WideCharToMultiByte(CP_ACP, 0, m_psz, -1, NULL, NULL, NULL, NULL); psz = (CHAR *)::CoTaskMemAlloc(cbNeeded); if (psz) { ::WideCharToMultiByte(CP_ACP, 0, m_psz, -1, psz, cbNeeded/sizeof(CHAR), NULL, NULL); } return psz; } return NULL; } void Attach(WCHAR * pszSrc) { m_psz = pszSrc; } WCHAR * Detach() { WCHAR * s = m_psz; m_psz = NULL; return s; } void Clear() { ::CoTaskMemFree(m_psz); m_psz = NULL; } bool operator!() const { return (m_psz == NULL); } HRESULT CopyToBSTR(BSTR * pbstr) { if (m_psz) { *pbstr = ::SysAllocString(m_psz); if (*pbstr == NULL) { return E_OUTOFMEMORY; } } else { *pbstr = NULL; } return S_OK; } void TrimToSize(ULONG ulNumChars) { if (m_psz && ulNumChars < Length()) { m_psz[ulNumChars] = 0; } } WCHAR * Compact() { if (m_psz) { ULONG cch = wcslen(m_psz); m_psz = (WCHAR *)::CoTaskMemRealloc(m_psz, (cch + 1) * sizeof(WCHAR)); } return m_psz; } WCHAR * ClearAndGrowTo(ULONG cch) { if (m_psz) { Clear(); } m_psz = (WCHAR *)::CoTaskMemAlloc(cch * sizeof(WCHAR)); return m_psz; } WCHAR * LTrim() { if (m_psz) { WCHAR * pszRead = m_psz; while (iswspace(*pszRead)) { pszRead++; } if (pszRead != m_psz) { WCHAR * pszWrite = m_psz; while (*pszRead) { *pszWrite++ = *pszRead++; } *pszWrite = '\0'; } } return m_psz; } WCHAR * RTrim() { if (m_psz) { WCHAR * pszTail = m_psz + wcslen(m_psz); WCHAR * pszZeroTerm = pszTail; while (pszZeroTerm > m_psz && iswspace(pszZeroTerm[-1])) { pszZeroTerm--; } if (pszZeroTerm != pszTail) { *pszZeroTerm = '\0'; } } return m_psz; } WCHAR * TrimBoth() { RTrim(); return LTrim(); } }; // // Simple inline function converts a ulong to a hex string. // inline void SpHexFromUlong(WCHAR * psz, ULONG ul) { const static WCHAR szHexChars[] = L"0123456789ABCDEF"; if (ul == 0) { psz[0] = L'0'; psz[1] = 0; } else { ULONG ulChars = 1; psz[0] = 0; while (ul) { memmove(psz + 1, psz, ulChars * sizeof(WCHAR)); psz[0] = szHexChars[ul % 16]; ul /= 16; ulChars++; } } } //=== Token helpers inline HRESULT SpGetTokenFromId( const WCHAR * pszTokenId, ISpObjectToken ** ppToken, BOOL fCreateIfNotExist = FALSE) { LPUNKNOWN pUnkOuter = nullptr; HRESULT hr = ::CoCreateInstance(CLSID_SpObjectToken, pUnkOuter, CLSCTX_ALL, IID_ISpObjectToken,reinterpret_cast(ppToken)); if (SUCCEEDED(hr)) { (*ppToken)->SetId(NULL, pszTokenId, fCreateIfNotExist); } return hr; } inline HRESULT SpGetCategoryFromId( const WCHAR * pszCategoryId, ISpObjectTokenCategory ** ppCategory, BOOL fCreateIfNotExist = FALSE) { LPUNKNOWN pUnkOuter = nullptr; HRESULT hr = ::CoCreateInstance(CLSID_SpObjectTokenCategory, pUnkOuter, CLSCTX_ALL, IID_ISpObjectTokenCategory, reinterpret_cast(ppCategory)); if (SUCCEEDED(hr)) { hr = (*ppCategory)->SetId(pszCategoryId, fCreateIfNotExist); } return hr; } inline HRESULT SpGetDefaultTokenIdFromCategoryId( const WCHAR * pszCategoryId, WCHAR ** ppszTokenId) { HRESULT hr; ISpObjectTokenCategory *cpCategory; hr = SpGetCategoryFromId(pszCategoryId, &cpCategory); if (SUCCEEDED(hr)) { hr = cpCategory->GetDefaultTokenId(ppszTokenId); } return hr; } inline HRESULT SpSetDefaultTokenIdForCategoryId( const WCHAR * pszCategoryId, const WCHAR * pszTokenId) { HRESULT hr; ISpObjectTokenCategory *cpCategory; hr = SpGetCategoryFromId(pszCategoryId, &cpCategory); if (SUCCEEDED(hr)) { hr = cpCategory->SetDefaultTokenId(pszTokenId); } return hr; } inline HRESULT SpGetDefaultTokenFromCategoryId( const WCHAR * pszCategoryId, ISpObjectToken ** ppToken, BOOL fCreateCategoryIfNotExist = TRUE) { HRESULT hr; ISpObjectTokenCategory *cpCategory; hr = SpGetCategoryFromId(pszCategoryId, &cpCategory, fCreateCategoryIfNotExist); if (SUCCEEDED(hr)) { WCHAR * pszTokenId; hr = cpCategory->GetDefaultTokenId(&pszTokenId); if (SUCCEEDED(hr)) { hr = SpGetTokenFromId(pszTokenId, ppToken); ::CoTaskMemFree(pszTokenId); } } return hr; } inline HRESULT SpSetDefaultTokenForCategoryId( const WCHAR * pszCategoryId, ISpObjectToken * pToken) { HRESULT hr; WCHAR * pszTokenId; hr = pToken->GetId(&pszTokenId); if (SUCCEEDED(hr)) { hr = SpSetDefaultTokenIdForCategoryId(pszCategoryId, pszTokenId); ::CoTaskMemFree(pszTokenId); } return hr; } inline HRESULT SpSetCommonTokenData( ISpObjectToken * pToken, const CLSID * pclsid, const WCHAR * pszLangIndependentName, LANGID langid, const WCHAR * pszLangDependentName, ISpDataKey ** ppDataKeyAttribs) { HRESULT hr = S_OK; // Set the new token's CLSID (if specified) if (SUCCEEDED(hr) && pclsid) { CSpDynamicString dstrClsid; hr = StringFromCLSID(*pclsid, &dstrClsid); if (SUCCEEDED(hr)) { hr = pToken->SetStringValue(SPTOKENVALUE_CLSID, dstrClsid); } } // Set the token's lang independent name if (SUCCEEDED(hr) && pszLangIndependentName) { hr = pToken->SetStringValue(NULL, pszLangIndependentName); } // Set the token's lang dependent name if (SUCCEEDED(hr) && pszLangDependentName) { WCHAR szLangId[10]; SpHexFromUlong(szLangId, langid); hr = pToken->SetStringValue(szLangId, pszLangDependentName); } // Open the attributes key if requested if (SUCCEEDED(hr) && ppDataKeyAttribs) { hr = pToken->CreateKey(L"Attributes", ppDataKeyAttribs); } return hr; } inline HRESULT SpCreateNewToken( const WCHAR * pszTokenId, ISpObjectToken ** ppToken) { HRESULT hr; // Forcefully create the token hr = SpGetTokenFromId(pszTokenId, ppToken, TRUE); return hr; } inline HRESULT SpCreateNewToken( const WCHAR * pszCategoryId, const WCHAR * pszTokenKeyName, ISpObjectToken ** ppToken) { HRESULT hr; // Forcefully create the category ISpObjectTokenCategory *cpCategory; hr = SpGetCategoryFromId(pszCategoryId, &cpCategory, TRUE); // Come up with a token key name if one wasn't specified CSpDynamicString dstrTokenKeyName; if (SUCCEEDED(hr)) { if (pszTokenKeyName == NULL) { GUID guidTokenKeyName; hr = CoCreateGuid(&guidTokenKeyName); if (SUCCEEDED(hr)) { hr = StringFromCLSID(guidTokenKeyName, &dstrTokenKeyName); } if (SUCCEEDED(hr)) { pszTokenKeyName = dstrTokenKeyName; } } } // Build the token id CSpDynamicString dstrTokenId; if (SUCCEEDED(hr)) { dstrTokenId = pszCategoryId; dstrTokenId.Append2(L"\\Tokens\\", pszTokenKeyName); } // Forcefully create the token if (SUCCEEDED(hr)) { hr = SpGetTokenFromId(dstrTokenId, ppToken, TRUE); } return hr; } inline HRESULT SpCreateNewTokenEx( const WCHAR * pszCategoryId, const WCHAR * pszTokenKeyName, const CLSID * pclsid, const WCHAR * pszLangIndependentName, LANGID langid, const WCHAR * pszLangDependentName, ISpObjectToken ** ppToken, ISpDataKey ** ppDataKeyAttribs) { HRESULT hr; // Create the new token hr = SpCreateNewToken(pszCategoryId, pszTokenKeyName, ppToken); // Now set the extra data if (SUCCEEDED(hr)) { hr = SpSetCommonTokenData( *ppToken, pclsid, pszLangIndependentName, langid, pszLangDependentName, ppDataKeyAttribs); } return hr; } inline HRESULT SpCreateNewTokenEx( const WCHAR * pszTokenId, const CLSID * pclsid, const WCHAR * pszLangIndependentName, LANGID langid, const WCHAR * pszLangDependentName, ISpObjectToken ** ppToken, ISpDataKey ** ppDataKeyAttribs) { HRESULT hr; // Create the new token hr = SpCreateNewToken(pszTokenId, ppToken); // Now set the extra data if (SUCCEEDED(hr)) { hr = SpSetCommonTokenData( *ppToken, pclsid, pszLangIndependentName, langid, pszLangDependentName, ppDataKeyAttribs); } return hr; } inline HRESULT SpEnumTokens( const WCHAR * pszCategoryId, const WCHAR * pszReqAttribs, const WCHAR * pszOptAttribs, IEnumSpObjectTokens ** ppEnum) { HRESULT hr = S_OK; ISpObjectTokenCategory *cpCategory; hr = SpGetCategoryFromId(pszCategoryId, &cpCategory); if (SUCCEEDED(hr)) { hr = cpCategory->EnumTokens( pszReqAttribs, pszOptAttribs, ppEnum); } return hr; } inline HRESULT SpFindBestToken( const WCHAR * pszCategoryId, const WCHAR * pszReqAttribs, const WCHAR * pszOptAttribs, ISpObjectToken **ppObjectToken) { HRESULT hr = S_OK; const WCHAR *pszVendorPreferred = L"VendorPreferred"; const unsigned long LenVendorPreferred = wcslen(pszVendorPreferred); // append VendorPreferred to the end of pszOptAttribs to force this preference ULONG ulLen = pszOptAttribs ? wcslen(pszOptAttribs) + LenVendorPreferred + 1 : LenVendorPreferred; WCHAR *pszOptAttribsVendorPref = (WCHAR*)_alloca((ulLen+1)*sizeof(WCHAR)); if (pszOptAttribsVendorPref) { if (pszOptAttribs) { wcscpy(pszOptAttribsVendorPref, pszOptAttribs); wcscat(pszOptAttribsVendorPref, L";"); wcscat(pszOptAttribsVendorPref, pszVendorPreferred); } else { wcscpy(pszOptAttribsVendorPref, pszVendorPreferred); } } else { hr = E_OUTOFMEMORY; } IEnumSpObjectTokens *cpEnum; if (SUCCEEDED(hr)) { hr = SpEnumTokens(pszCategoryId, pszReqAttribs, pszOptAttribsVendorPref, &cpEnum); } if (SUCCEEDED(hr)) { hr = cpEnum->Next(1, ppObjectToken, NULL); if (hr == S_FALSE) { *ppObjectToken = NULL; hr = SPERR_NOT_FOUND; } } if (hr != SPERR_NOT_FOUND) { } return hr; } /*template HRESULT SpCreateObjectFromToken(ISpObjectToken * pToken, T ** ppObject, IUnknown * pUnkOuter = NULL, DWORD dwClsCtxt = CLSCTX_ALL) { HRESULT hr; hr = pToken->CreateInstance(pUnkOuter, dwClsCtxt, __uuidof(T), (void **)ppObject); return hr; } template HRESULT SpCreateObjectFromTokenId(const WCHAR * pszTokenId, T ** ppObject, IUnknown * pUnkOuter = NULL, DWORD dwClsCtxt = CLSCTX_ALL) { ISpObjectToken * pToken; HRESULT hr = SpGetTokenFromId(pszTokenId, &pToken); if (SUCCEEDED(hr)) { hr = SpCreateObjectFromToken(pToken, ppObject, pUnkOuter, dwClsCtxt); pToken->Release(); } return hr; }*/ /* template HRESULT SpCreateDefaultObjectFromCategoryId(const WCHAR * pszCategoryId, T ** ppObject, IUnknown * pUnkOuter = NULL, DWORD dwClsCtxt = CLSCTX_ALL) { ISpObjectToken * pToken; HRESULT hr = SpGetDefaultTokenFromCategoryId(pszCategoryId, &pToken); if (SUCCEEDED(hr)) { hr = SpCreateObjectFromToken(pToken, ppObject, pUnkOuter, dwClsCtxt); pToken->Release(); } return hr; } template HRESULT SpCreateBestObject( const WCHAR * pszCategoryId, const WCHAR * pszReqAttribs, const WCHAR * pszOptAttribs, T ** ppObject, IUnknown * pUnkOuter = NULL, DWORD dwClsCtxt = CLSCTX_ALL) { HRESULT hr; ISpObjectToken *cpToken; hr = SpFindBestToken(pszCategoryId, pszReqAttribs, pszOptAttribs, &cpToken); if (SUCCEEDED(hr)) { hr = SpCreateObjectFromToken(cpToken, ppObject, pUnkOuter, dwClsCtxt); } if (hr != SPERR_NOT_FOUND) { } return hr; }*/ /*HRESULT SpCreateBestObject( const WCHAR * pszCategoryId, const WCHAR * pszReqAttribs, const WCHAR * pszOptAttribs, ISpPhoneConverter ** ** ppObject, IUnknown * pUnkOuter = NULL, DWORD dwClsCtxt = CLSCTX_ALL) { HRESULT hr; ISpObjectToken *cpToken; hr = SpFindBestToken(pszCategoryId, pszReqAttribs, pszOptAttribs, &cpToken); if (SUCCEEDED(hr)) { hr = SpCreateObjectFromToken(cpToken, ppObject, pUnkOuter, dwClsCtxt); } if (hr != SPERR_NOT_FOUND) { } return hr; }*/ /*inline HRESULT SpCreatePhoneConverter( LANGID LangID, const WCHAR * pszReqAttribs, const WCHAR * pszOptAttribs, ISpPhoneConverter ** ppPhoneConverter) { HRESULT hr; if (LangID == 0) { hr = E_INVALIDARG; } else { CSpDynamicString dstrReqAttribs; if (pszReqAttribs) { dstrReqAttribs = pszReqAttribs; dstrReqAttribs.Append(L";"); } WCHAR szLang[MAX_PATH]; SpHexFromUlong(szLang, LangID); WCHAR szLangCondition[MAX_PATH]; wcscpy(szLangCondition, L"Language="); wcscat(szLangCondition, szLang); dstrReqAttribs.Append(szLangCondition); hr = SpCreateBestObject(SPCAT_PHONECONVERTERS, dstrReqAttribs, pszOptAttribs, ppPhoneConverter); } if (hr != SPERR_NOT_FOUND) { } return hr; }*/ /**************************************************************************** * SpHrFromWin32 * *---------------* * Description: * This inline function works around a basic problem with the macro * HRESULT_FROM_WIN32. The macro forces the expresion in ( ) to be evaluated * two times. By using this inline function, the expression will only be * evaluated once. * * Returns: * HRESULT of converted Win32 error code * *****************************************************************************/ inline HRESULT SpHrFromWin32(DWORD dwErr) { return HRESULT_FROM_WIN32(dwErr); } /**************************************************************************** * SpHrFromLastWin32Error * *------------------------* * Description: * This simple inline function is used to return a converted HRESULT * from the Win32 function ::GetLastError. Note that using HRESULT_FROM_WIN32 * will evaluate the error code twice so we don't want to use: * * HRESULT_FROM_WIN32(::GetLastError()) * * since that will call GetLastError twice. * On Win98 and WinMe ::GetLastError() returns 0 for some functions (see MSDN). * We therefore check for that and return E_FAIL. This function should only be * called in an error case since it will always return an error code! * * Returns: * HRESULT for ::GetLastError() * *****************************************************************************/ inline HRESULT SpHrFromLastWin32Error() { DWORD dw = ::GetLastError(); return (dw == 0) ? E_FAIL : SpHrFromWin32(dw); } /**************************************************************************** * SpGetUserDefaultUILanguage * *----------------------------* * Description: * Returns the default user interface language, using a method * appropriate to the platform (Windows 9x, Windows NT, or Windows 2000) * * Returns: * Default UI language * *****************************************************************************/ inline LANGID SpGetUserDefaultUILanguage(void) { HRESULT hr = S_OK; LANGID wUILang = 0; OSVERSIONINFO Osv ; Osv.dwOSVersionInfoSize = sizeof(Osv) ; if(!GetVersionEx(&Osv)) { hr = SpHrFromLastWin32Error(); } // Get the UI language by one of three methods, depending on the system else if(Osv.dwPlatformId != VER_PLATFORM_WIN32_NT) { // Case 1: Running on Windows 9x. Get the system UI language from registry: CHAR szData[32]; DWORD dwSize = sizeof(szData) ; HKEY hKey; long lRet = RegOpenKeyEx( HKEY_USERS, ".Default\\Control Panel\\desktop\\ResourceLocale", 0, KEY_READ, &hKey); #ifdef _WIN32_WCE_BUG_10655 if (lRet == ERROR_INVALID_PARAMETER) { lRet = ERROR_FILE_NOT_FOUND; } #endif // _WIN32_WCE_BUG_10655 hr = SpHrFromWin32(lRet); if (SUCCEEDED(hr)) { lRet = RegQueryValueEx( hKey, "", NULL, NULL, (BYTE *)szData, &dwSize); #ifdef _WIN32_WCE_BUG_10655 if(lRet == ERROR_INVALID_PARAMETER) { lRet = ERROR_FILE_NOT_FOUND; } #endif //_WIN32_WCE_BUG_10655 hr = SpHrFromWin32(lRet); ::RegCloseKey(hKey) ; } if (SUCCEEDED(hr)) { // Convert string to number wUILang = (LANGID) strtol(szData, NULL, 16) ; } } else if (Osv.dwMajorVersion >= 5.0) { // Case 2: Running on Windows 2000 or later. Use GetUserDefaultUILanguage to find // the user's prefered UI language HMODULE hMKernel32 = ::LoadLibraryW(L"kernel32.dll") ; if (hMKernel32 == NULL) { hr = SpHrFromLastWin32Error(); } else { LANGID (WINAPI *pfnGetUserDefaultUILanguage) () = (LANGID (WINAPI *)(void)) #ifdef _WIN32_WCE GetProcAddress(hMKernel32, L"GetUserDefaultUILanguage") ; #else GetProcAddress(hMKernel32, "GetUserDefaultUILanguage") ; #endif if(NULL != pfnGetUserDefaultUILanguage) { wUILang = pfnGetUserDefaultUILanguage() ; } else { // GetProcAddress failed hr = SpHrFromLastWin32Error(); } ::FreeLibrary(hMKernel32); } } else { // Case 3: Running on Windows NT 4.0 or earlier. Get UI language // from locale of .default user in registry: // HKEY_USERS\.DEFAULT\Control Panel\International\Locale WCHAR szData[32] ; DWORD dwSize = sizeof(szData) ; HKEY hKey ; LONG lRet = RegOpenKeyEx(HKEY_USERS, ".DEFAULT\\Control Panel\\International", 0, KEY_READ, &hKey); #ifdef _WIN32_WCE_BUG_10655 if(lRet == ERROR_INVALID_PARAMETER) { lRet = ERROR_FILE_NOT_FOUND; } #endif //_WIN32_WCE_BUG_10655 hr = SpHrFromWin32(lRet); if (SUCCEEDED(hr)) { lRet = RegQueryValueEx( hKey, "Locale", NULL, NULL, (BYTE *)szData, &dwSize); #ifdef _WIN32_WCE_BUG_10655 if(lRet == ERROR_INVALID_PARAMETER) { lRet = ERROR_FILE_NOT_FOUND; } #endif //_WIN32_WCE_BUG_10655 hr = SpHrFromWin32(lRet); ::RegCloseKey(hKey); } if (SUCCEEDED(hr)) { // Convert string to number wUILang = (LANGID) wcstol(szData, NULL, 16) ; if(0x0401 == wUILang || // Arabic 0x040d == wUILang || // Hebrew 0x041e == wUILang // Thai ) { // Special case these to the English UI. // These versions of Windows NT 4.0 were enabled only, i.e., the // UI was English. However, the registry setting // HKEY_USERS\.DEFAULT\Control Panel\International\Locale was set // to the respective locale for application compatibility. wUILang = MAKELANGID(LANG_ENGLISH, SUBLANG_ENGLISH_US) ; } } } return (wUILang ? wUILang : ::GetUserDefaultLangID()); // In failure case, try our best! } inline HRESULT SpGetDescription(ISpObjectToken * pObjToken, WCHAR ** ppszDescription, LANGID Language = SpGetUserDefaultUILanguage()) { WCHAR szLangId[10]; SpHexFromUlong(szLangId, Language); HRESULT hr = pObjToken->GetStringValue(szLangId, ppszDescription); if (hr == SPERR_NOT_FOUND) { hr = pObjToken->GetStringValue(NULL, ppszDescription); } return hr; } inline HRESULT SpSetDescription(ISpObjectToken * pObjToken, const WCHAR * pszDescription, LANGID Language = SpGetUserDefaultUILanguage(), BOOL fSetLangIndependentId = TRUE) { WCHAR szLangId[10]; SpHexFromUlong(szLangId, Language); HRESULT hr = pObjToken->SetStringValue(szLangId, pszDescription); if (SUCCEEDED(hr) && fSetLangIndependentId) { hr = pObjToken->SetStringValue(NULL, pszDescription); } return hr; } /**************************************************************************** * SpConvertStreamFormatEnum * *---------------------------* * Description: * This method converts the specified stream format into a wave format * structure. * *****************************************************************************/ inline HRESULT SpConvertStreamFormatEnum(SPSTREAMFORMAT eFormat, GUID * pFormatId, WAVEFORMATEX ** ppCoMemWaveFormatEx) { HRESULT hr = S_OK; if(pFormatId==NULL || ::IsBadWritePtr(pFormatId, sizeof(*pFormatId)) || ppCoMemWaveFormatEx==NULL || ::IsBadWritePtr(ppCoMemWaveFormatEx, sizeof(*ppCoMemWaveFormatEx))) { return E_INVALIDARG; } const GUID * pFmtGuid = &GUID_NULL; // Assume failure case if( eFormat >= SPSF_8kHz8BitMono && eFormat <= SPSF_48kHz16BitStereo ) { WAVEFORMATEX * pwfex = (WAVEFORMATEX *)::CoTaskMemAlloc(sizeof(WAVEFORMATEX)); *ppCoMemWaveFormatEx = pwfex; if (pwfex) { DWORD dwIndex = eFormat - SPSF_8kHz8BitMono; BOOL bIsStereo = dwIndex & 0x1; BOOL bIs16 = dwIndex & 0x2; DWORD dwKHZ = (dwIndex & 0x3c) >> 2; static const DWORD adwKHZ[] = { 8000, 11025, 12000, 16000, 22050, 24000, 32000, 44100, 48000 }; pwfex->wFormatTag = WAVE_FORMAT_PCM; pwfex->nChannels = pwfex->nBlockAlign = (WORD)(bIsStereo ? 2 : 1); pwfex->nSamplesPerSec = adwKHZ[dwKHZ]; pwfex->wBitsPerSample = 8; if (bIs16) { pwfex->wBitsPerSample *= 2; pwfex->nBlockAlign *= 2; } pwfex->nAvgBytesPerSec = pwfex->nSamplesPerSec * pwfex->nBlockAlign; pwfex->cbSize = 0; pFmtGuid = &SPDFID_WaveFormatEx; } else { hr = E_OUTOFMEMORY; } } else if( eFormat == SPSF_TrueSpeech_8kHz1BitMono ) { int NumBytes = sizeof( WAVEFORMATEX ) + 32; WAVEFORMATEX * pwfex = (WAVEFORMATEX *)::CoTaskMemAlloc( NumBytes ); *ppCoMemWaveFormatEx = pwfex; if( pwfex ) { memset( pwfex, 0, NumBytes ); pwfex->wFormatTag = WAVE_FORMAT_DSPGROUP_TRUESPEECH; pwfex->nChannels = 1; pwfex->nSamplesPerSec = 8000; pwfex->nAvgBytesPerSec = 1067; pwfex->nBlockAlign = 32; pwfex->wBitsPerSample = 1; pwfex->cbSize = 32; BYTE* pExtra = ((BYTE*)pwfex) + sizeof( WAVEFORMATEX ); pExtra[0] = 1; pExtra[2] = 0xF0; pFmtGuid = &SPDFID_WaveFormatEx; } else { hr = E_OUTOFMEMORY; } } else if( (eFormat >= SPSF_CCITT_ALaw_8kHzMono ) && (eFormat <= SPSF_CCITT_ALaw_44kHzStereo ) ) { WAVEFORMATEX * pwfex = (WAVEFORMATEX *)::CoTaskMemAlloc( sizeof(WAVEFORMATEX) ); *ppCoMemWaveFormatEx = pwfex; if( pwfex ) { memset( pwfex, 0, sizeof(WAVEFORMATEX) ); DWORD dwIndex = eFormat - SPSF_CCITT_ALaw_8kHzMono; DWORD dwKHZ = dwIndex / 2; static const DWORD adwKHZ[] = { 8000, 11025, 22050, 44100 }; BOOL bIsStereo = dwIndex & 0x1; pwfex->wFormatTag = WAVE_FORMAT_ALAW; pwfex->nChannels = pwfex->nBlockAlign = (WORD)(bIsStereo ? 2 : 1); pwfex->nSamplesPerSec = adwKHZ[dwKHZ]; pwfex->wBitsPerSample = 8; pwfex->nAvgBytesPerSec = pwfex->nSamplesPerSec * pwfex->nBlockAlign; pwfex->cbSize = 0; pFmtGuid = &SPDFID_WaveFormatEx; } else { hr = E_OUTOFMEMORY; } } else if( (eFormat >= SPSF_CCITT_uLaw_8kHzMono ) && (eFormat <= SPSF_CCITT_uLaw_44kHzStereo ) ) { WAVEFORMATEX * pwfex = (WAVEFORMATEX *)::CoTaskMemAlloc( sizeof(WAVEFORMATEX) ); *ppCoMemWaveFormatEx = pwfex; if( pwfex ) { memset( pwfex, 0, sizeof(WAVEFORMATEX) ); DWORD dwIndex = eFormat - SPSF_CCITT_uLaw_8kHzMono; DWORD dwKHZ = dwIndex / 2; static const DWORD adwKHZ[] = { 8000, 11025, 22050, 44100 }; BOOL bIsStereo = dwIndex & 0x1; pwfex->wFormatTag = WAVE_FORMAT_MULAW; pwfex->nChannels = pwfex->nBlockAlign = (WORD)(bIsStereo ? 2 : 1); pwfex->nSamplesPerSec = adwKHZ[dwKHZ]; pwfex->wBitsPerSample = 8; pwfex->nAvgBytesPerSec = pwfex->nSamplesPerSec * pwfex->nBlockAlign; pwfex->cbSize = 0; pFmtGuid = &SPDFID_WaveFormatEx; } else { hr = E_OUTOFMEMORY; } } else if( (eFormat >= SPSF_ADPCM_8kHzMono ) && (eFormat <= SPSF_ADPCM_44kHzStereo ) ) { int NumBytes = sizeof( WAVEFORMATEX ) + 32; WAVEFORMATEX * pwfex = (WAVEFORMATEX *)::CoTaskMemAlloc( NumBytes ); *ppCoMemWaveFormatEx = pwfex; if( pwfex ) { //--- Some of these values seem odd. We used what the codec told us. static const DWORD adwKHZ[] = { 8000, 11025, 22050, 44100 }; static const DWORD BytesPerSec[] = { 4096, 8192, 5644, 11289, 11155, 22311, 22179, 44359 }; static const DWORD BlockAlign[] = { 256, 256, 512, 1024 }; static const BYTE Extra811[32] = { 0xF4, 0x01, 0x07, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x02, 0x00, 0xFF, 0x00, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x40, 0x00, 0xF0, 0x00, 0x00, 0x00, 0xCC, 0x01, 0x30, 0xFF, 0x88, 0x01, 0x18, 0xFF }; static const BYTE Extra22[32] = { 0xF4, 0x03, 0x07, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x02, 0x00, 0xFF, 0x00, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x40, 0x00, 0xF0, 0x00, 0x00, 0x00, 0xCC, 0x01, 0x30, 0xFF, 0x88, 0x01, 0x18, 0xFF }; static const BYTE Extra44[32] = { 0xF4, 0x07, 0x07, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x02, 0x00, 0xFF, 0x00, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x40, 0x00, 0xF0, 0x00, 0x00, 0x00, 0xCC, 0x01, 0x30, 0xFF, 0x88, 0x01, 0x18, 0xFF }; static const BYTE* Extra[4] = { Extra811, Extra811, Extra22, Extra44 }; memset( pwfex, 0, NumBytes ); DWORD dwIndex = eFormat - SPSF_ADPCM_8kHzMono; DWORD dwKHZ = dwIndex / 2; BOOL bIsStereo = dwIndex & 0x1; pwfex->wFormatTag = WAVE_FORMAT_ADPCM; pwfex->nChannels = (WORD)(bIsStereo ? 2 : 1); pwfex->nSamplesPerSec = adwKHZ[dwKHZ]; pwfex->nAvgBytesPerSec = BytesPerSec[dwIndex]; pwfex->nBlockAlign = (WORD)(BlockAlign[dwKHZ] * pwfex->nChannels); pwfex->wBitsPerSample = 4; pwfex->cbSize = 32; BYTE* pExtra = ((BYTE*)pwfex) + sizeof( WAVEFORMATEX ); memcpy( pExtra, Extra[dwKHZ], 32 ); pFmtGuid = &SPDFID_WaveFormatEx; } else { hr = E_OUTOFMEMORY; } } else if( (eFormat >= SPSF_GSM610_8kHzMono ) && (eFormat <= SPSF_GSM610_44kHzMono ) ) { int NumBytes = sizeof( WAVEFORMATEX ) + 2; WAVEFORMATEX * pwfex = (WAVEFORMATEX *)::CoTaskMemAlloc( NumBytes ); *ppCoMemWaveFormatEx = pwfex; if( pwfex ) { //--- Some of these values seem odd. We used what the codec told us. static const DWORD adwKHZ[] = { 8000, 11025, 22050, 44100 }; static const DWORD BytesPerSec[] = { 1625, 2239, 4478, 8957 }; memset( pwfex, 0, NumBytes ); DWORD dwIndex = eFormat - SPSF_GSM610_8kHzMono; pwfex->wFormatTag = WAVE_FORMAT_GSM610; pwfex->nChannels = 1; pwfex->nSamplesPerSec = adwKHZ[dwIndex]; pwfex->nAvgBytesPerSec = BytesPerSec[dwIndex]; pwfex->nBlockAlign = 65; pwfex->wBitsPerSample = 0; pwfex->cbSize = 2; BYTE* pExtra = ((BYTE*)pwfex) + sizeof( WAVEFORMATEX ); pExtra[0] = 0x40; pExtra[1] = 0x01; pFmtGuid = &SPDFID_WaveFormatEx; } else { hr = E_OUTOFMEMORY; } } else { *ppCoMemWaveFormatEx = NULL; switch (eFormat) { case SPSF_NoAssignedFormat: break; case SPSF_Text: pFmtGuid = &SPDFID_Text; break; default: hr = E_INVALIDARG; break; } } *pFormatId = *pFmtGuid; return hr; } class CSpStreamFormat { public: GUID m_guidFormatId; WAVEFORMATEX * m_pCoMemWaveFormatEx; static CoMemCopyWFEX(const WAVEFORMATEX * pSrc, WAVEFORMATEX ** ppCoMemWFEX) { ULONG cb = sizeof(WAVEFORMATEX) + pSrc->cbSize; *ppCoMemWFEX = (WAVEFORMATEX *)::CoTaskMemAlloc(cb); if (*ppCoMemWFEX) { memcpy(*ppCoMemWFEX, pSrc, cb); return S_OK; } else { return E_OUTOFMEMORY; } } CSpStreamFormat() { m_guidFormatId = GUID_NULL; m_pCoMemWaveFormatEx = NULL; } CSpStreamFormat(SPSTREAMFORMAT eFormat, HRESULT * phr) { *phr = SpConvertStreamFormatEnum(eFormat, &m_guidFormatId, &m_pCoMemWaveFormatEx); } CSpStreamFormat(const WAVEFORMATEX * pWaveFormatEx, HRESULT * phr) { *phr = CoMemCopyWFEX(pWaveFormatEx, &m_pCoMemWaveFormatEx); m_guidFormatId = SUCCEEDED(*phr) ? SPDFID_WaveFormatEx : GUID_NULL; } ~CSpStreamFormat() { ::CoTaskMemFree(m_pCoMemWaveFormatEx); } void Clear() { ::CoTaskMemFree(m_pCoMemWaveFormatEx); m_pCoMemWaveFormatEx = NULL; memset(&m_guidFormatId, 0, sizeof(m_guidFormatId)); } const GUID & FormatId() const { return m_guidFormatId; } const WAVEFORMATEX * WaveFormatExPtr() const { return m_pCoMemWaveFormatEx; } HRESULT AssignFormat(SPSTREAMFORMAT eFormat) { ::CoTaskMemFree(m_pCoMemWaveFormatEx); return SpConvertStreamFormatEnum(eFormat, &m_guidFormatId, &m_pCoMemWaveFormatEx); } HRESULT AssignFormat(ISpStreamFormat * pStream) { ::CoTaskMemFree(m_pCoMemWaveFormatEx); m_pCoMemWaveFormatEx = NULL; return pStream->GetFormat(&m_guidFormatId, &m_pCoMemWaveFormatEx); } HRESULT AssignFormat(const WAVEFORMATEX * pWaveFormatEx) { ::CoTaskMemFree(m_pCoMemWaveFormatEx); HRESULT hr = CoMemCopyWFEX(pWaveFormatEx, &m_pCoMemWaveFormatEx); m_guidFormatId = SUCCEEDED(hr) ? SPDFID_WaveFormatEx : GUID_NULL; return hr; } HRESULT AssignFormat(REFGUID rguidFormatId, const WAVEFORMATEX * pWaveFormatEx) { HRESULT hr = S_OK; m_guidFormatId = rguidFormatId; ::CoTaskMemFree(m_pCoMemWaveFormatEx); m_pCoMemWaveFormatEx = NULL; if (rguidFormatId == SPDFID_WaveFormatEx) { if (::IsBadReadPtr(pWaveFormatEx, sizeof(*pWaveFormatEx))) { hr = E_INVALIDARG; } else { hr = CoMemCopyWFEX(pWaveFormatEx, &m_pCoMemWaveFormatEx); } if (FAILED(hr)) { m_guidFormatId = GUID_NULL; } } return hr; } BOOL IsEqual(REFGUID rguidFormatId, const WAVEFORMATEX * pwfex) const { if (rguidFormatId == m_guidFormatId) { if (m_pCoMemWaveFormatEx) { if (pwfex && pwfex->cbSize == m_pCoMemWaveFormatEx->cbSize && memcmp(m_pCoMemWaveFormatEx, pwfex, sizeof(WAVEFORMATEX) + pwfex->cbSize) == 0) { return TRUE; } } else { return (pwfex == NULL); } } return FALSE; } HRESULT ParamValidateAssignFormat(REFGUID rguidFormatId, const WAVEFORMATEX * pWaveFormatEx, BOOL fRequireWaveFormat = FALSE) { if ((pWaveFormatEx && (::IsBadReadPtr(pWaveFormatEx, sizeof(*pWaveFormatEx)) || rguidFormatId != SPDFID_WaveFormatEx)) || (fRequireWaveFormat && pWaveFormatEx == NULL)) { return E_INVALIDARG; } return AssignFormat(rguidFormatId, pWaveFormatEx); } SPSTREAMFORMAT ComputeFormatEnum() { if (m_guidFormatId == GUID_NULL) { return SPSF_NoAssignedFormat; } if (m_guidFormatId == SPDFID_Text) { return SPSF_Text; } if (m_guidFormatId != SPDFID_WaveFormatEx) { return SPSF_NonStandardFormat; } // // It is a WAVEFORMATEX. Now determine which type it is and convert. // DWORD dwIndex = 0; switch (m_pCoMemWaveFormatEx->wFormatTag) { case WAVE_FORMAT_PCM: { switch (m_pCoMemWaveFormatEx->nChannels) { case 1: break; case 2: dwIndex |= 1; break; default: return SPSF_ExtendedAudioFormat; } switch (m_pCoMemWaveFormatEx->wBitsPerSample) { case 8: break; case 16: dwIndex |= 2; break; default: return SPSF_ExtendedAudioFormat; } switch (m_pCoMemWaveFormatEx->nSamplesPerSec) { case 48000: dwIndex += 4; // Fall through case 44100: dwIndex += 4; // Fall through case 32000: dwIndex += 4; // Fall through case 24000: dwIndex += 4; // Fall through case 22050: dwIndex += 4; // Fall through case 16000: dwIndex += 4; // Fall through case 12000: dwIndex += 4; // Fall through case 11025: dwIndex += 4; // Fall through case 8000: break; default: return SPSF_ExtendedAudioFormat; } return static_cast(SPSF_8kHz8BitMono + dwIndex); } case WAVE_FORMAT_DSPGROUP_TRUESPEECH: { return SPSF_TrueSpeech_8kHz1BitMono; } case WAVE_FORMAT_ALAW: // fall through case WAVE_FORMAT_MULAW: case WAVE_FORMAT_ADPCM: { switch (m_pCoMemWaveFormatEx->nChannels) { case 1: break; case 2: dwIndex |= 1; break; default: return SPSF_ExtendedAudioFormat; } if(m_pCoMemWaveFormatEx->wFormatTag == WAVE_FORMAT_ADPCM) { if(m_pCoMemWaveFormatEx->wBitsPerSample != 4) { return SPSF_ExtendedAudioFormat; } } else if(m_pCoMemWaveFormatEx->wBitsPerSample != 8) { return SPSF_ExtendedAudioFormat; } switch (m_pCoMemWaveFormatEx->nSamplesPerSec) { case 44100: dwIndex += 2; // Fall through case 22050: dwIndex += 2; // Fall through case 11025: dwIndex += 2; // Fall through case 8000: break; default: return SPSF_ExtendedAudioFormat; } switch( m_pCoMemWaveFormatEx->wFormatTag ) { case WAVE_FORMAT_ALAW: return static_cast(SPSF_CCITT_ALaw_8kHzMono + dwIndex); case WAVE_FORMAT_MULAW: return static_cast(SPSF_CCITT_uLaw_8kHzMono + dwIndex); case WAVE_FORMAT_ADPCM: return static_cast(SPSF_ADPCM_8kHzMono + dwIndex); } } case WAVE_FORMAT_GSM610: { if( m_pCoMemWaveFormatEx->nChannels != 1 ) { return SPSF_ExtendedAudioFormat; } switch (m_pCoMemWaveFormatEx->nSamplesPerSec) { case 44100: dwIndex = 3; break; case 22050: dwIndex = 2; break; case 11025: dwIndex = 1; break; case 8000: dwIndex = 0; break; default: return SPSF_ExtendedAudioFormat; } return static_cast(SPSF_GSM610_8kHzMono + dwIndex); } default: return SPSF_ExtendedAudioFormat; break; } } void DetachTo(CSpStreamFormat & Other) { ::CoTaskMemFree(Other.m_pCoMemWaveFormatEx); Other.m_guidFormatId = m_guidFormatId; Other.m_pCoMemWaveFormatEx = m_pCoMemWaveFormatEx; m_pCoMemWaveFormatEx = NULL; memset(&m_guidFormatId, 0, sizeof(m_guidFormatId)); } void DetachTo(GUID * pFormatId, WAVEFORMATEX ** ppCoMemWaveFormatEx) { *pFormatId = m_guidFormatId; *ppCoMemWaveFormatEx = m_pCoMemWaveFormatEx; m_pCoMemWaveFormatEx = NULL; memset(&m_guidFormatId, 0, sizeof(m_guidFormatId)); } HRESULT CopyTo(GUID * pFormatId, WAVEFORMATEX ** ppCoMemWFEX) const { HRESULT hr = S_OK; *pFormatId = m_guidFormatId; if (m_pCoMemWaveFormatEx) { hr = CoMemCopyWFEX(m_pCoMemWaveFormatEx, ppCoMemWFEX); if (FAILED(hr)) { memset(pFormatId, 0, sizeof(*pFormatId)); } } else { *ppCoMemWFEX = NULL; } return hr; } HRESULT CopyTo(CSpStreamFormat & Other) const { ::CoTaskMemFree(Other.m_pCoMemWaveFormatEx); return CopyTo(&Other.m_guidFormatId, &Other.m_pCoMemWaveFormatEx); } HRESULT AssignFormat(const CSpStreamFormat & Src) { return Src.CopyTo(*this); } HRESULT ParamValidateCopyTo(GUID * pFormatId, WAVEFORMATEX ** ppCoMemWFEX) const { if (::IsBadWritePtr(pFormatId, sizeof(*pFormatId)) || ::IsBadWritePtr(ppCoMemWFEX, sizeof(*ppCoMemWFEX))) { return E_POINTER; } return CopyTo(pFormatId, ppCoMemWFEX); } BOOL operator==(const CSpStreamFormat & Other) const { return IsEqual(Other.m_guidFormatId, Other.m_pCoMemWaveFormatEx); } BOOL operator!=(const CSpStreamFormat & Other) const { return !IsEqual(Other.m_guidFormatId, Other.m_pCoMemWaveFormatEx); } ULONG SerializeSize() const { ULONG cb = sizeof(ULONG) + sizeof(m_guidFormatId); if (m_pCoMemWaveFormatEx) { cb += sizeof(WAVEFORMATEX) + m_pCoMemWaveFormatEx->cbSize + 3; // Add 3 to round up cb -= cb % 4; // Round to DWORD } return cb; } ULONG Serialize(BYTE * pBuffer) const { ULONG cb = SerializeSize(); *((UNALIGNED ULONG *)pBuffer) = cb; pBuffer += sizeof(ULONG); *((UNALIGNED GUID *)pBuffer) = m_guidFormatId; if (m_pCoMemWaveFormatEx) { pBuffer += sizeof(m_guidFormatId); memcpy(pBuffer, m_pCoMemWaveFormatEx, sizeof(WAVEFORMATEX) + m_pCoMemWaveFormatEx->cbSize); } return cb; } HRESULT Deserialize(const BYTE * pBuffer, ULONG * pcbUsed) { HRESULT hr = S_OK; ::CoTaskMemFree(m_pCoMemWaveFormatEx); m_pCoMemWaveFormatEx = NULL; *pcbUsed = *((UNALIGNED ULONG *)pBuffer); pBuffer += sizeof(ULONG); // Misaligment exception is generated for SHx platform. // Marking pointer as UNALIGNED does not help. #ifndef _WIN32_WCE m_guidFormatId = *((UNALIGNED GUID *)pBuffer); #else memcpy(&m_guidFormatId, pBuffer, sizeof(GUID)); #endif if (*pcbUsed > sizeof(GUID) + sizeof(ULONG)) { pBuffer += sizeof(m_guidFormatId); hr = CoMemCopyWFEX((const WAVEFORMATEX *)pBuffer, &m_pCoMemWaveFormatEx); if (FAILED(hr)) { m_guidFormatId = GUID_NULL; } } return hr; } }; // Return the default codepage given a LCID. // Note some of the newer locales do not have associated Windows codepages. For these, we return UTF-8. inline UINT SpCodePageFromLcid(LCID lcid) { char achCodePage[6]; return (0 != GetLocaleInfoA(lcid, LOCALE_IDEFAULTANSICODEPAGE, achCodePage, sizeof(achCodePage))) ? atoi(achCodePage) : 65001; } /**************************************************************************** * SpClearEvent * *--------------* * Description: * Helper function that can be used by clients that do not use the CSpEvent * class. * * Returns: * *****************************************************************************/ inline void SpClearEvent(SPEVENT * pe) { if( pe->elParamType != SPEI_UNDEFINED) { if( pe->elParamType == SPET_LPARAM_IS_POINTER || pe->elParamType == SPET_LPARAM_IS_STRING) { ::CoTaskMemFree((void *)pe->lParam); } else if (pe->elParamType == SPET_LPARAM_IS_TOKEN || pe->elParamType == SPET_LPARAM_IS_OBJECT) { ((IUnknown*)pe->lParam)->Release(); } } memset(pe, 0, sizeof(*pe)); } /**************************************************************************** * SpInitEvent * *-------------* * Description: * * Returns: * *****************************************************************************/ inline void SpInitEvent(SPEVENT * pe) { memset(pe, 0, sizeof(*pe)); } /**************************************************************************** * SpEventSerializeSize * *----------------------* * Description: * Computes the required size of a buffer to serialize an event. The caller * must specify which type of serialized event is desired -- either SPSERIALIZEDEVENT * or SPSERIALIZEDEVENT64. * * Returns: * Size in bytes required to seriailze the event. * ****************************************************************************/ // WCE compiler does not work propertly with template #ifndef _WIN32_WCE template inline ULONG SpEventSerializeSize(const SPEVENT * pEvent) { ULONG ulSize = sizeof(T); #else inline ULONG SpEventSerializeSize(const SPEVENT * pEvent, ULONG ulSize) { #endif //_WIN32_WCE if( ( pEvent->elParamType == SPET_LPARAM_IS_POINTER ) && pEvent->lParam ) { ulSize += ULONG(pEvent->wParam); } else if ((pEvent->elParamType == SPET_LPARAM_IS_STRING) && pEvent->lParam != NULL) { ulSize += (wcslen((WCHAR*)pEvent->lParam) + 1) * sizeof( WCHAR ); } else if( pEvent->elParamType == SPET_LPARAM_IS_TOKEN ) { CSpDynamicString dstrObjectId; if( ((ISpObjectToken*)(pEvent->lParam))->GetId( &dstrObjectId ) == S_OK ) { ulSize += (dstrObjectId.Length() + 1) * sizeof( WCHAR ); } } // Round up to nearest DWORD ulSize += 3; ulSize -= ulSize % 4; return ulSize; } /**************************************************************************** * SpSerializedEventSize * *-----------------------* * Description: * Returns the size, in bytes, used by a serialized event. The caller can * pass a pointer to either a SPSERIAILZEDEVENT or SPSERIALIZEDEVENT64 structure. * * Returns: * Number of bytes used by serizlied event * ********************************************************************* RAL ***/ // WCE compiler does not work propertly with template #ifndef _WIN32_WCE template inline ULONG SpSerializedEventSize(const T * pSerEvent) { ULONG ulSize = sizeof(T); if( ( pSerEvent->elParamType == SPET_LPARAM_IS_POINTER ) && pSerEvent->SerializedlParam ) { ulSize += ULONG(pSerEvent->SerializedwParam); } else if ((pSerEvent->elParamType == SPET_LPARAM_IS_STRING || pSerEvent->elParamType == SPET_LPARAM_IS_TOKEN) && pSerEvent->SerializedlParam != NULL) { ulSize += (wcslen((WCHAR*)(pSerEvent + 1)) + 1) * sizeof( WCHAR ); } // Round up to nearest DWORD ulSize += 3; ulSize -= ulSize % 4; return ulSize; } #else //_WIN32_WCE inline ULONG SpSerializedEventSize(const SPSERIALIZEDEVENT * pSerEvent, ULONG ulSize) { if( ( pSerEvent->elParamType == SPET_LPARAM_IS_POINTER ) && pSerEvent->SerializedlParam ) { ulSize += ULONG(pSerEvent->SerializedwParam); } else if ((pSerEvent->elParamType == SPET_LPARAM_IS_STRING || pSerEvent->elParamType == SPET_LPARAM_IS_TOKEN) && pSerEvent->SerializedlParam != NULL) { ulSize += (wcslen((WCHAR*)(pSerEvent + 1)) + 1) * sizeof( WCHAR ); } // Round up to nearest DWORD ulSize += 3; ulSize -= ulSize % 4; return ulSize; } inline ULONG SpSerializedEventSize(const SPSERIALIZEDEVENT64 * pSerEvent, ULONG ulSize) { if( ( pSerEvent->elParamType == SPET_LPARAM_IS_POINTER ) && pSerEvent->SerializedlParam ) { ulSize += ULONG(pSerEvent->SerializedwParam); } else if ((pSerEvent->elParamType == SPET_LPARAM_IS_STRING || pSerEvent->elParamType == SPET_LPARAM_IS_TOKEN) && pSerEvent->SerializedlParam != NULL) { ulSize += (wcslen((WCHAR*)(pSerEvent + 1)) + 1) * sizeof( WCHAR ); } // Round up to nearest DWORD ulSize += 3; ulSize -= ulSize % 4; return ulSize; } #endif //_WIN32_WCE /*** CSpEvent helper class * */ class CSpEvent : public SPEVENT { public: CSpEvent() { SpInitEvent(this); } ~CSpEvent() { SpClearEvent(this); } // If you need to take the address of a CSpEvent that is not const, use the AddrOf() method // which will do debug checking of parameters. If you encounter this problem when calling // GetEvents from an event source, you may want to use the GetFrom() method of this class. const SPEVENT * operator&() { return this; } CSpEvent * AddrOf() { // Note: This method does not ASSERT since we assume the caller knows what they are doing. return this; } void Clear() { SpClearEvent(this); } HRESULT CopyTo(SPEVENT * pDestEvent) const { memcpy(pDestEvent, this, sizeof(*pDestEvent)); if ((elParamType == SPET_LPARAM_IS_POINTER) && lParam) { pDestEvent->lParam = (LPARAM)::CoTaskMemAlloc(wParam); if (pDestEvent->lParam) { memcpy((void *)pDestEvent->lParam, (void *)lParam, wParam); } else { pDestEvent->eEventId = SPEI_UNDEFINED; return E_OUTOFMEMORY; } } else if (elParamType == SPET_LPARAM_IS_STRING && lParam != NULL) { pDestEvent->lParam = (LPARAM)::CoTaskMemAlloc((wcslen((WCHAR*)lParam) + 1) * sizeof(WCHAR)); if (pDestEvent->lParam) { wcscpy((WCHAR*)pDestEvent->lParam, (WCHAR*)lParam); } else { pDestEvent->eEventId = SPEI_UNDEFINED; return E_OUTOFMEMORY; } } else if (elParamType == SPET_LPARAM_IS_TOKEN || elParamType == SPET_LPARAM_IS_OBJECT) { ((IUnknown*)lParam)->AddRef(); } return S_OK; } HRESULT GetFrom(ISpEventSource * pEventSrc) { SpClearEvent(this); return pEventSrc->GetEvents(1, this, NULL); } HRESULT CopyFrom(const SPEVENT * pSrcEvent) { SpClearEvent(this); return static_cast(pSrcEvent)->CopyTo(this); } void Detach(SPEVENT * pDestEvent = NULL) { if (pDestEvent) { memcpy(pDestEvent, this, sizeof(*pDestEvent)); } memset(this, 0, sizeof(*this)); } template ULONG SerializeSize() const { return SpEventSerializeSize(this); } // Call this method with either SPSERIALIZEDEVENT or SPSERIALIZEDEVENT64 template void Serialize(T * pSerEvent) const { pSerEvent->eEventId = this->eEventId; pSerEvent->elParamType = this->elParamType; pSerEvent->ulStreamNum = this->ulStreamNum; pSerEvent->ullAudioStreamOffset = this->ullAudioStreamOffset; pSerEvent->SerializedwParam = static_cast(this->wParam); pSerEvent->SerializedlParam = static_cast(this->lParam); if (lParam) { switch(elParamType) { case SPET_LPARAM_IS_POINTER: memcpy(pSerEvent + 1, (void *)lParam, wParam); pSerEvent->SerializedlParam = sizeof(T); break; case SPET_LPARAM_IS_STRING: wcscpy((WCHAR *)(pSerEvent + 1), (WCHAR*)lParam); pSerEvent->SerializedlParam = sizeof(T); break; case SPET_LPARAM_IS_TOKEN: { CSpDynamicString dstrObjectId; if( SUCCEEDED( ((ISpObjectToken*)lParam)->GetId( &dstrObjectId ) ) ) { pSerEvent->SerializedwParam = (dstrObjectId.Length() + 1) * sizeof( WCHAR );; memcpy( pSerEvent + 1, (void *)dstrObjectId.m_psz, static_cast(pSerEvent->SerializedwParam) ); } pSerEvent->SerializedlParam = sizeof(T); } break; default: break; } } } template HRESULT Serialize(T ** ppCoMemSerEvent, ULONG * pcbSerEvent) const { // WCE compiler does not work propertly with template #ifndef _WIN32_WCE *pcbSerEvent = SpEventSerializeSize(this); #else *pcbSerEvent = SpEventSerializeSize(this, sizeof(** ppCoMemSerEvent)); #endif *ppCoMemSerEvent = (T *)::CoTaskMemAlloc(*pcbSerEvent); if (*ppCoMemSerEvent) { Serialize(*ppCoMemSerEvent); return S_OK; } else { *pcbSerEvent = 0; return E_OUTOFMEMORY; } } // Call this method with either SPSERIALIZEDEVENT or SPSERIALIZEDEVENT64 template HRESULT Deserialize(const T * pSerEvent, ULONG * pcbUsed = NULL) { Clear(); HRESULT hr = S_OK; const UNALIGNED T * pTemp = pSerEvent; this->eEventId = pTemp->eEventId; this->elParamType = pTemp->elParamType; this->ulStreamNum = pTemp->ulStreamNum; this->ullAudioStreamOffset = pTemp->ullAudioStreamOffset; this->wParam = static_cast(pTemp->SerializedwParam); this->lParam = static_cast(pTemp->SerializedlParam); if (pTemp->SerializedlParam) { ULONG cbAlloc = 0; switch (pTemp->elParamType) { case SPET_LPARAM_IS_POINTER: cbAlloc = static_cast(wParam); break; case SPET_LPARAM_IS_STRING: cbAlloc = sizeof(WCHAR) * (1 + wcslen((const WCHAR *)(pTemp + 1))); break; case SPET_LPARAM_IS_TOKEN: { ULONG ulDataOffset = ULONG(lParam); hr = SpGetTokenFromId( (const WCHAR*)(pTemp + 1), (ISpObjectToken **)&lParam ); wParam = 0; } break; } if (cbAlloc) { void * pvBuff = ::CoTaskMemAlloc(cbAlloc); this->lParam = (LPARAM)pvBuff; if (pvBuff) { memcpy(pvBuff, pTemp + 1, cbAlloc); } else { hr = E_OUTOFMEMORY; } } } if( SUCCEEDED( hr ) && pcbUsed ) { // WCE compiler does not work propertly with template #ifndef _WIN32_WCE *pcbUsed = SpEventSerializeSize(this); #else *pcbUsed = SpEventSerializeSize(this, sizeof(*pTemp)); #endif } return hr; } // // Helpers for access to events. Performs run-time checks in debug and casts // data to the appropriate types // SPPHONEID Phoneme() const { return (SPPHONEID)LOWORD(lParam); } SPVISEMES Viseme() const { return (SPVISEMES)LOWORD(lParam); } ULONG InputWordPos() const { return ULONG(lParam); } ULONG InputWordLen() const { return ULONG(wParam); } ULONG InputSentPos() const { return ULONG(lParam); } ULONG InputSentLen() const { return ULONG(wParam); } ISpObjectToken * ObjectToken() const { return (ISpObjectToken *)lParam; } ISpObjectToken * VoiceToken() const // More explicit check than ObjectToken() { return ObjectToken(); } BOOL PersistVoiceChange() const { return (BOOL)wParam; } IUnknown * Object() const { return (IUnknown*)lParam; } ISpRecoResult * RecoResult() const { return (ISpRecoResult *)Object(); } BOOL IsPaused() { return (BOOL)(wParam & SPREF_AutoPause); } BOOL IsEmulated() { return (BOOL)(wParam & SPREF_Emulated); } const WCHAR * String() const { return (const WCHAR*)lParam; } const WCHAR * BookmarkName() const { return String(); } const WCHAR * RequestTypeOfUI() const { return String(); } SPRECOSTATE RecoState() const { return static_cast(wParam); } const WCHAR * PropertyName() const { // Note: Don't use String() method here since in the case of string attributes, the elParamType // field specifies LPARAM_IS_POINTER, but the attribute name IS the first string in this buffer return (const WCHAR*)lParam; } const LONG PropertyNumValue() const { return static_cast(wParam); } const WCHAR * PropertyStringValue() const { // Search for the first NULL and return pointer to the char past it. const WCHAR *psz; for (psz = (const WCHAR *)lParam; *psz; psz++) {} return psz + 1; } SPINTERFERENCE Interference() const { return static_cast(lParam); } HRESULT EndStreamResult() const { return static_cast(lParam); } BOOL InputStreamReleased() const { return (wParam & SPESF_STREAM_RELEASED) ? TRUE : FALSE; } }; class CSpPhrasePtr { public: SPPHRASE * m_pPhrase; CSpPhrasePtr() : m_pPhrase(NULL) {} CSpPhrasePtr(ISpPhrase * pPhraseObj, HRESULT * phr) { *phr = pPhraseObj->GetPhrase(&m_pPhrase); } ~CSpPhrasePtr() { ::CoTaskMemFree(m_pPhrase); } //The assert on operator& usually indicates a bug. If this is really //what is needed, however, take the address of the m_pPhrase member explicitly. SPPHRASE ** operator&() { return &m_pPhrase; } operator SPPHRASE *() const { return m_pPhrase; } SPPHRASE & operator*() const { return *m_pPhrase; } SPPHRASE * operator->() const { return m_pPhrase; } bool operator!() const { return (m_pPhrase == NULL); } void Clear() { if (m_pPhrase) { ::CoTaskMemFree(m_pPhrase); m_pPhrase = NULL; } } HRESULT GetFrom(ISpPhrase * pPhraseObj) { Clear(); return pPhraseObj->GetPhrase(&m_pPhrase); } }; template class CSpCoTaskMemPtr { public: T * m_pT; CSpCoTaskMemPtr() : m_pT(NULL) {} CSpCoTaskMemPtr(void * pv) : m_pT((T *)pv) {} CSpCoTaskMemPtr(ULONG cElements, HRESULT * phr) { m_pT = (T *)::CoTaskMemAlloc(cElements * sizeof(T)); *phr = m_pT ? S_OK : E_OUTOFMEMORY; } ~CSpCoTaskMemPtr() { ::CoTaskMemFree(m_pT); } void Clear() { if (m_pT) { ::CoTaskMemFree(m_pT); m_pT = NULL; } } HRESULT Alloc(ULONG cArrayElements = 1) { m_pT = (T *)::CoTaskMemRealloc(m_pT, sizeof(T) * cArrayElements); return (m_pT ? S_OK : E_OUTOFMEMORY); } void Attach(void * pv) { Clear(); m_pT = (T *)pv; } T * Detatch() { T * pT = m_pT; m_pT = NULL; return pT; } //The assert on operator& usually indicates a bug. If this is really //what is needed, however, take the address of the m_pT member explicitly. T ** operator&() { return &m_pT; } T * operator->() { return m_pT; } operator T *() { return m_pT; } bool operator!() const { return (m_pT == NULL); } }; /**** Helper function used to create a new phrase object from an array of test words. Each word in the string is converted to a phrase element. This is useful to create a phrase to pass to the EmulateRecognition method. The method can convert standard words as well as words with the "/display_text/lexical_form/pronounciation;" word format. You can also specify the DisplayAttributes for each element if desired. If prgDispAttribs is NULL then the DisplayAttribs for each element default to SPAF_ONE_TRAILING_SPACE. ****/ /*inline HRESULT CreatePhraseFromWordArray(const WCHAR ** ppWords, ULONG cWords, SPDISPLYATTRIBUTES * prgDispAttribs, ISpPhraseBuilder **ppResultPhrase, LANGID LangId = 0, ISpPhoneConverter *cpPhoneConv = NULL) { HRESULT hr = S_OK; if ( cWords == 0 || ppWords == NULL || ::IsBadReadPtr(ppWords, sizeof(*ppWords) * cWords ) ) { return E_INVALIDARG; } if ( prgDispAttribs != NULL && ::IsBadReadPtr(prgDispAttribs, sizeof(*prgDispAttribs) * cWords ) ) { return E_INVALIDARG; } ULONG cTotalChars = 0; ULONG i; WCHAR** pStringPtrArray = (WCHAR**)::CoTaskMemAlloc( cWords * sizeof(WCHAR *)); if ( !pStringPtrArray ) { return E_OUTOFMEMORY; } for (i = 0; i < cWords; i++) { cTotalChars += wcslen(ppWords[i])+1; } CSpDynamicString dsText(cTotalChars); if(dsText.m_psz == NULL) { ::CoTaskMemFree(pStringPtrArray); return E_OUTOFMEMORY; } CSpDynamicString dsPhoneId(cTotalChars); if(dsPhoneId.m_psz == NULL) { ::CoTaskMemFree(pStringPtrArray); return E_OUTOFMEMORY; } SPPHONEID* pphoneId = dsPhoneId; SPPHRASE Phrase; memset(&Phrase, 0, sizeof(Phrase)); Phrase.cbSize = sizeof(Phrase); if(LangId == 0) { LangId = SpGetUserDefaultUILanguage(); } if(cpPhoneConv == NULL) { hr = SpCreatePhoneConverter(LangId, NULL, NULL, &cpPhoneConv); if(FAILED(hr)) { ::CoTaskMemFree(pStringPtrArray); return hr; } } SPPHRASEELEMENT *pPhraseElement = new SPPHRASEELEMENT[cWords]; if(pPhraseElement == NULL) { ::CoTaskMemFree(pStringPtrArray); return E_OUTOFMEMORY; } memset(pPhraseElement, 0, sizeof(SPPHRASEELEMENT) * cWords); // !!! WCHAR * pText = dsText; for (i = 0; SUCCEEDED(hr) && i < cWords; i++) { WCHAR *p = pText; pStringPtrArray[i] = pText; wcscpy( pText, ppWords[i] ); pText += wcslen( p ) + 1; if (*p == L'/') { //This is a compound word WCHAR* pszFirstPart = ++p; WCHAR* pszSecondPart = NULL; WCHAR* pszThirdPart = NULL; while (*p && *p != L'/') { p++; } if (*p == L'/') { //It means we stop at the second '/' *p = L'\0'; pszSecondPart = ++p; while (*p && *p != L'/') { p++; } if (*p == L'/') { //It means we stop at the third '/' *p = L'\0'; pszThirdPart = ++p; } } pPhraseElement[i].pszDisplayText = pszFirstPart; pPhraseElement[i].pszLexicalForm = pszSecondPart ? pszSecondPart : pszFirstPart; if ( pszThirdPart) { hr = cpPhoneConv->PhoneToId(pszThirdPart, pphoneId); if (SUCCEEDED(hr)) { pPhraseElement[i].pszPronunciation = pphoneId; pphoneId += wcslen(pphoneId) + 1; } } } else { //It is the simple format, only have one form, use it for everything. pPhraseElement[i].pszDisplayText = NULL; pPhraseElement[i].pszLexicalForm = p; pPhraseElement[i].pszPronunciation = NULL; } pPhraseElement[i].bDisplayAttributes = (BYTE)(prgDispAttribs ? prgDispAttribs[i] : SPAF_ONE_TRAILING_SPACE); pPhraseElement[i].RequiredConfidence = SP_NORMAL_CONFIDENCE; pPhraseElement[i].ActualConfidence = SP_NORMAL_CONFIDENCE; } Phrase.Rule.ulCountOfElements = cWords; Phrase.pElements = pPhraseElement; Phrase.LangID = LangId; ISpPhraseBuilder *cpPhrase; if (SUCCEEDED(hr)) { hr = cpPhrase.CoCreateInstance(CLSID_SpPhraseBuilder); } if (SUCCEEDED(hr)) { hr = cpPhrase->InitFromPhrase(&Phrase); } if (SUCCEEDED(hr)) { *ppResultPhrase = cpPhrase.Detach(); } delete pPhraseElement; ::CoTaskMemFree(pStringPtrArray); return hr; }*/ /**** Helper function used to create a new phrase object from a test string. Each word in the string is converted to a phrase element. This is useful to create a phrase to pass to the EmulateRecognition method. The method can convert standard words as well as words with the "/display_text/lexical_form/pronounciation;" word format ****/ /*inline HRESULT CreatePhraseFromText(const WCHAR *pszOriginalText, ISpPhraseBuilder **ppResultPhrase, LANGID LangId = 0, ISpPhoneConverter *cpPhoneConv = NULL) { HRESULT hr = S_OK; //We first trim the input text CSpDynamicString dsText(pszOriginalText); if(dsText.m_psz == NULL) { return E_OUTOFMEMORY; } dsText.TrimBoth(); ULONG cWords = 0; BOOL fInCompoundword = FALSE; // Set first array pointer (if *p). WCHAR *p = dsText; while (*p) { if( iswspace(*p) && !fInCompoundword) { cWords++; *p++ = L'\0'; while (*p && iswspace(*p)) { *p++ = L'\0'; } // Add new array pointer. Use vector. } else if (*p == L'/' && !fInCompoundword) { fInCompoundword = TRUE; } else if (*p == L';' && fInCompoundword) { fInCompoundword = FALSE; *p++ = L'\0'; // Add new array element. } else { p++; } } cWords++; WCHAR** pStringPtrArray = (WCHAR**)::CoTaskMemAlloc( cWords * sizeof(WCHAR *)); if ( !pStringPtrArray ) { hr = E_OUTOFMEMORY; } if ( SUCCEEDED( hr ) ) { p = dsText; for (ULONG i=0; i