// // This module provides the following functions: // // CvtDlgToDlgEx - Converts a DLGTEMPLATE to a DLGTEMPLATEEX // // #include "ctlspriv.h" #include "dlgcvt.h" // // Define the amount (bytes) the stream buffer grows when required. // It will grow enough to satisfy the required write PLUS this // amount. // #ifdef DEBUG # define STREAM_GROW_BYTES 32 // Exercise stream growth. #else # define STREAM_GROW_BYTES 512 #endif // // Simple MIN/MAX inline helpers. // #if (defined UNIX && defined ux10) //IEUNIX: hp's version of "/usr/local/include/sys/param.h defines MAX and MIN //macro's and breaks hp's build #undef MAX(a,b) #undef MIN(a,b) #endif //UNIX && ux10 template inline const T& MIN(const T& a, const T& b) { return a < b ? a : b; } template inline const T& MAX(const T& a, const T& b) { return a > b ? a : b; } // // This class implements a simple dynamic stream that grows as you // add data to it. It's modeled after the strstream class provided // by the C++ std lib. Unlike the std lib implementation, this one // doesn't require C++ EH to be enabled. If comctl32 compiled with // C++ EH enabled, I would have used strstream instead. // [brianau - 10/5/98] // class CByteStream { public: explicit CByteStream(int cbDefGrow = 512); ~CByteStream(void); // // Used as argument to AlignXXXX member functions. // enum AlignType { eAlignWrite, eAlignRead }; // // Basic read/write functions. // int Read(LPVOID pb, int cb); int Write(const VOID *pb, int cb); // // Determine if there was an error when reading or // writing to the stream. // bool ReadError(void) const { return m_bReadErr; } bool WriteError(void) const { return m_bWriteErr; } // // Reset the stream read or write pointer. // void ResetRead(void) { m_pbRead = m_pbBuf; m_bReadErr = false; } void ResetWrite(void) { m_pbWrite = m_pbBuf; m_bWriteErr = false; } // // Reset the stream. // void Reset(void); // // These functions align the read and write stream pointers. // void AlignReadWord(void) { Align(eAlignRead, sizeof(WORD)); } void AlignReadDword(void) { Align(eAlignRead, sizeof(DWORD)); } void AlignReadQword(void) { Align(eAlignRead, sizeof(ULONGLONG)); } void AlignWriteWord(void) { Align(eAlignWrite, sizeof(WORD)); } void AlignWriteDword(void) { Align(eAlignWrite, sizeof(DWORD)); } void AlignWriteQword(void) { Align(eAlignWrite, sizeof(ULONGLONG)); } // // GetBuffer returns the address of the stream buffer in memory. // The buffer is "frozen" so it will not be released if the stream // object is destroyed. At this point, you own the buffer. // If bPermanent is false, you can call ReleaseBuffer to return // control of the buffer to the stream object. // LPBYTE GetBuffer(bool bPermanent = false); // // ReleaseBuffer returns control of the buffer obtained with GetBuffer // to the stream object. // bool ReleaseBuffer(LPBYTE pbBuf); // // Overload the insertion and extraction operators so we can // work like a normal std lib stream class. // template CByteStream& operator >> (T& x) { Read(&x, sizeof(x)); return *this; } template CByteStream& operator << (const T& x) { Write(&x, sizeof(x)); return *this; } private: int m_cbDefGrow; // Default amount (bytes) to grow when expanding buffer. LPBYTE m_pbBuf; // Addr of allocated buffer. LPBYTE m_pbRead; // Addr for next read. LPBYTE m_pbWrite; // Addr for next write. LPBYTE m_pbEnd; // Addr of byte following last byte in buffer. bool m_bWriteErr; // Any read errors? bool m_bReadErr; // Any write errors? bool m_bOwnsBuf; // true == delete buffer in dtor. // // Expand the buffer as needed. // bool GrowBuffer(int cb = 0); // // Align the read or write buffer pointer. // Used internally by the AlignXXXXX member functions. // void Align(AlignType a, size_t n); // // Internal consistency checks for debug builds. // void Validate(void) const; // // Prevent copy. // CByteStream(const CByteStream& rhs); CByteStream& operator = (const CByteStream& rhs); }; // // Class for converting in-memory dialog templates between the two // structures DLGTEMPLATE <-> DLGTEMPLATEEX. // // Currently, the object only converts from DLGTEMPLATE -> DLGTEMPLATEEX. // It would be simple to create the code for the inverse conversion. However, // it's currently not needed so I didn't create it. // class CDlgTemplateConverter { public: explicit CDlgTemplateConverter(int iCharSet = DEFAULT_CHARSET) : m_iCharset(iCharSet), m_stm(STREAM_GROW_BYTES) { } ~CDlgTemplateConverter(void) { } HRESULT DlgToDlgEx(LPDLGTEMPLATE pTemplateIn, LPDLGTEMPLATEEX *ppTemplateOut); HRESULT DlgExToDlg(LPDLGTEMPLATEEX pTemplateIn, LPDLGTEMPLATE *ppTemplateOut) { return E_NOTIMPL; } private: int m_iCharset; CByteStream m_stm; // For converted template. #ifndef UNIX HRESULT DlgHdrToDlgEx(CByteStream& s, LPWORD *ppw); HRESULT DlgItemToDlgEx(CByteStream& s, LPWORD *ppw); #else HRESULT DlgHdrToDlgEx(CByteStream& s, LPDWORD *ppw); HRESULT DlgItemToDlgEx(CByteStream& s, LPDWORD *ppw); #endif HRESULT DlgExHdrToDlg(CByteStream& s, LPWORD *ppw) { return E_NOTIMPL; } HRESULT DlgExItemToDlg(CByteStream& s, LPWORD *ppw) { return E_NOTIMPL; } // // Copy a string from pszW into a CByteStream object. // Copies at most cch chars. If cch is -1, assumes the string is // nul-terminated and will copy all chars in string including // terminating NULL. // int CopyStringW(CByteStream& stm, LPWSTR pszW, int cch = -1); // // Prevent copy. // CDlgTemplateConverter(const CDlgTemplateConverter& rhs); CDlgTemplateConverter& operator = (const CDlgTemplateConverter& rhs); }; // // Generic alignment function. // Give it an address and an alignment size and it returns // the address adjusted for the requested alignment. // // n : 2 = 16-bit // 4 = 32-bit // 8 = 64-bit // LPVOID Align(LPVOID pv, size_t n) { const ULONG_PTR x = static_cast(n) - 1; return reinterpret_cast((reinterpret_cast(pv) + x) & ~x); } inline LPVOID AlignWord(LPVOID pv) { return ::Align(pv, sizeof(WORD)); } inline LPVOID AlignDWord(LPVOID pv) { return ::Align(pv, sizeof(DWORD)); } inline LPVOID AlignQWord(LPVOID pv) { return ::Align(pv, sizeof(ULONGLONG)); } CByteStream::CByteStream( int cbDefGrow ) : m_cbDefGrow(MAX(cbDefGrow, 1)), m_pbBuf(NULL), m_pbRead(NULL), m_pbWrite(NULL), m_pbEnd(NULL), m_bWriteErr(false), m_bReadErr(false), m_bOwnsBuf(true) { } CByteStream::~CByteStream( void ) { if (m_bOwnsBuf && NULL != m_pbBuf) { LocalFree(m_pbBuf); } } // // Simple checks to validate stream state. // In non-debug builds, this will be a no-op. // Use ASSERT_VALIDSTREAM macro. // void CByteStream::Validate( void ) const { ASSERT(m_pbEnd >= m_pbBuf); ASSERT(m_pbWrite >= m_pbBuf); ASSERT(m_pbRead >= m_pbBuf); ASSERT(m_pbWrite <= m_pbEnd); ASSERT(m_pbRead <= m_pbEnd); } #ifdef DEBUG # define ASSERT_VALIDSTREAM(ps) ps->Validate() #else # define ASSERT_VALIDSTREAM(ps) #endif // // Read "cb" bytes from the stream and write them to // the location specified in "pb". Return number // of bytes read. Note that if we don't "own" the // buffer (i.e. the client has called GetBuffer but // not ReleaseBuffer), no read will occur. // int CByteStream::Read( LPVOID pb, int cb ) { ASSERT_VALIDSTREAM(this); int cbRead = 0; if (m_bOwnsBuf) { cbRead = MIN(static_cast(m_pbEnd - m_pbRead), cb); CopyMemory(pb, m_pbRead, cbRead); m_pbRead += cbRead; if (cb != cbRead) m_bReadErr = true; } ASSERT_VALIDSTREAM(this); return cbRead; } // // Write "cb" bytes from location "pb" into the stream. // Return number of bytes written. Note that if we don't "own" the // buffer (i.e. the client has called GetBuffer but // not ReleaseBuffer), no write will occur. // int CByteStream::Write( const VOID *pb, int cb ) { ASSERT_VALIDSTREAM(this); int cbWritten = 0; if (m_bOwnsBuf) { if (m_pbWrite + cb < m_pbEnd || GrowBuffer(static_cast(m_pbEnd - m_pbBuf) + cb + m_cbDefGrow)) { CopyMemory(m_pbWrite, pb, cb); m_pbWrite += cb; cbWritten = cb; } else m_bWriteErr = true; } ASSERT_VALIDSTREAM(this); return cbWritten; } // // Reallocate the buffer by cb or m_cbDefGrow. // Copy existing contents to new buffer. All internal // pointers are updated. // bool CByteStream::GrowBuffer( int cb // optional. Default is 0 causing us to use m_cbDefGrow. ) { bool bResult = false; int cbGrow = 0 < cb ? cb : m_cbDefGrow; ULONG_PTR ulReadOfs = m_pbRead - m_pbBuf; ULONG_PTR ulWriteOfs = m_pbWrite - m_pbBuf; ULONG_PTR cbAlloc = m_pbEnd - m_pbBuf; LPBYTE pNew = static_cast(LocalAlloc(LPTR, cbAlloc + cbGrow)); if (NULL != pNew) { if (NULL != m_pbBuf) { CopyMemory(pNew, m_pbBuf, cbAlloc); LocalFree(m_pbBuf); } m_pbBuf = pNew; m_pbRead = m_pbBuf + ulReadOfs; m_pbWrite = m_pbBuf + ulWriteOfs; m_pbEnd = m_pbBuf + cbAlloc + cbGrow; bResult = true; } ASSERT_VALIDSTREAM(this); return bResult; } // // Align the read or write pointer on the stream. // The write pointer is aligned by padding skipped bytes with 0. // void CByteStream::Align( CByteStream::AlignType a, size_t n ) { static const BYTE fill[8] = {0}; if (m_bOwnsBuf) { switch(a) { case eAlignWrite: Write(fill, static_cast(reinterpret_cast(::Align(m_pbWrite, n)) - m_pbWrite)); break; case eAlignRead: m_pbRead = reinterpret_cast(::Align(m_pbRead, n)); if (m_pbRead >= m_pbEnd) m_bReadErr = true; break; default: break; } } ASSERT_VALIDSTREAM(this); } // // Caller takes ownership of the buffer. // LPBYTE CByteStream::GetBuffer( bool bPermanent // optional. Default is false. ) { LPBYTE pbRet = m_pbBuf; if (bPermanent) { // // Caller now permanently owns the buffer. // Can't return it through ReleaseBuffer(). // Reset the internal stream control values. // m_pbBuf = m_pbWrite = m_pbRead = m_pbEnd = NULL; m_bWriteErr = m_bReadErr = false; m_bOwnsBuf = true; } else { // // Caller now owns the buffer but it can be returned // through ReleaseBuffer(). // m_bOwnsBuf = false; } return pbRet; } // // Take back ownership of the buffer. // Returns: // // true = CByteStream object took back ownership. // false = CByteStream object couldn't take ownership. // bool CByteStream::ReleaseBuffer( LPBYTE pbBuf ) { if (pbBuf == m_pbBuf) { m_bOwnsBuf = true; return true; } return false; } // // Reset the stream. // void CByteStream::Reset( void ) { if (NULL != m_pbBuf) { LocalFree(m_pbBuf); } m_pbBuf = m_pbWrite = m_pbRead = m_pbEnd = NULL; m_bWriteErr = m_bReadErr = false; m_bOwnsBuf = true; } // // Copy one or more WORDs from the location provided in "pszW" into // the stream. If cch is -1, it's assumed that the string is nul-terminated. // Returns the number of WCHARs written. // int CDlgTemplateConverter::CopyStringW( CByteStream& stm, LPWSTR pszW, int cch ) { if (-1 == cch) cch = lstrlenW(pszW) + 1; return stm.Write(pszW, cch * sizeof(WCHAR)) / sizeof(WCHAR); } // // Convert a DLGTEMPLATE structure to a DLGTEMPLATEEX structure. // pti is the address of the DLGTEMPLATE to be converted. // ppto points to a LPDLGTEMPLATEEX ptr to receive the address of the // converted template structure. Caller is responsible for freeing // this buffer with LocalFree. // // Returns: E_OUTOFMEMORY, NOERROR // HRESULT CDlgTemplateConverter::DlgToDlgEx( LPDLGTEMPLATE pti, LPDLGTEMPLATEEX *ppto ) { HRESULT hr = NOERROR; #ifndef UNIX LPWORD pw = reinterpret_cast(pti); #else LPDWORD pw = reinterpret_cast(pti); #endif *ppto = NULL; // // Reset the stream. // m_stm.Reset(); // // Convert DLGTEMPLATE -> DLGTEMPLATEEX // hr = DlgHdrToDlgEx(m_stm, &pw); // // Convert each DLGITEMTEMPLATE -> DLGITEMTEMPLATEEX // for (int i = 0; i < pti->cdit && SUCCEEDED(hr); i++) { #ifndef UNIX pw = reinterpret_cast(::AlignDWord(pw)); #else pw = reinterpret_cast(::AlignDWord(pw)); #endif m_stm.AlignWriteDword(); hr = DlgItemToDlgEx(m_stm, &pw); } if (SUCCEEDED(hr)) { // // Return the buffer to the caller. Buffer is permanently // detached from the stream object so the stream's dtor // won't free it. // *ppto = reinterpret_cast(m_stm.GetBuffer(true)); } return hr; }; // // Convert DLGTEMPLATE -> DLGTEMPLATEEX // // s = Stream to hold converted template. // ppw = Address of current read pointer into the template being converted. // On exit, the referenced pointer is updated with the current read location. // // Returns: E_OUTOFMEMORY, NOERROR // HRESULT CDlgTemplateConverter::DlgHdrToDlgEx( CByteStream& s, #ifndef UNIX LPWORD *ppw #else LPDWORD *ppw #endif ) { #ifndef UNIX LPWORD pw = *ppw; #else LPDWORD pw = *ppw; #endif LPDLGTEMPLATE pt = reinterpret_cast(pw); // // Convert the fixed-length stuff. // s << static_cast(1) // wDlgVer << static_cast(0xFFFF) // wSignature << static_cast(0) // dwHelpID << static_cast(pt->dwExtendedStyle) << static_cast(pt->style) << static_cast(pt->cdit) << static_cast(pt->x) << static_cast(pt->y) << static_cast(pt->cx) << static_cast(pt->cy); // // Arrays are always WORD aligned. // #ifndef UNIX pw = reinterpret_cast(::AlignWord(reinterpret_cast(pw) + sizeof(DLGTEMPLATE))); s.AlignWriteWord(); #else pw = reinterpret_cast(::AlignDWord(reinterpret_cast(pw) + sizeof(DLGTEMPLATE))); s.AlignWriteDword(); #endif // // Copy the menu array. // switch(*pw) { case 0xFFFF: s << *pw++; // // Fall through... // case 0x0000: s << *pw++; break; default: #ifndef UNIX pw += CopyStringW(s, (LPWSTR)pw); #else pw += CopyStringW (s, reinterpret_cast(pw)); #endif break; }; // // Copy the class array. // switch(*pw) { case 0xFFFF: s << *pw++; // // Fall through... // case 0x0000: s << *pw++; break; default: #ifndef UNIX pw += CopyStringW(s, (LPWSTR)pw); #else pw += CopyStringW (s, reinterpret_cast(pw)); #endif break; }; // // Copy the title array. // switch(*pw) { case 0x0000: s << *pw++; break; default: #ifndef UNIX pw += CopyStringW(s, (LPWSTR)pw); #else pw += CopyStringW (s, reinterpret_cast(pw)); #endif break; }; // // Copy font information if it's present. // if (DS_SETFONT & pt->style) { s << *pw++; // pt size s << static_cast(FW_NORMAL); // weight (default, not in DLGTEMPLATE) s << static_cast(FALSE); // italic (default, not in DLGTEMPLATE) s << static_cast(m_iCharset); // charset (default if not given, // not in DLGTEMPLATE) #ifndef UNIX pw += CopyStringW(s, (LPWSTR)pw); #else pw += CopyStringW (s, reinterpret_cast(pw)); #endif } *ppw = pw; return s.WriteError() ? E_OUTOFMEMORY : NOERROR; } // // Convert DLGITEMTEMPLATE -> DLGITEMTEMPLATEEX // // s = Stream to hold converted template. // ppw = Address of current read pointer into the template being converted. // On exit, the referenced pointer is updated with the current read location. // // Returns: E_OUTOFMEMORY, NOERROR // HRESULT CDlgTemplateConverter::DlgItemToDlgEx( CByteStream& s, #ifndef UNIX LPWORD *ppw #else LPDWORD *ppw #endif ) { #ifndef UNIX LPWORD pw = *ppw; #else LPDWORD pw = *ppw; #endif LPDLGITEMTEMPLATE pit = reinterpret_cast(pw); // // Convert the fixed-length stuff. // s << static_cast(0) // dwHelpID << static_cast(pit->dwExtendedStyle) << static_cast(pit->style) << static_cast(pit->x) << static_cast(pit->y) << static_cast(pit->cx) << static_cast(pit->cy) << static_cast(pit->id); // // Arrays are always word aligned. // #ifndef UNIX pw = reinterpret_cast(::AlignWord(reinterpret_cast(pw) + sizeof(DLGITEMTEMPLATE))); s.AlignWriteWord(); #else pw = reinterpret_cast(::AlignWord(reinterpret_cast(pw) + sizeof(DLGITEMTEMPLATE))); s.AlignWriteDword(); #endif // // Copy the class array. // switch(*pw) { case 0xFFFF: s << *pw++; s << *pw++; // Class code. break; default: #ifndef UNIX pw += CopyStringW(s, (LPWSTR)pw); #else pw += CopyStringW (s, reinterpret_cast(pw)); #endif break; }; // // Copy the title array. // switch(*pw) { case 0xFFFF: s << *pw++; s << *pw++; // Resource ordinal value. break; default: #ifndef UNIX pw += CopyStringW(s, (LPWSTR)pw); #else pw += CopyStringW (s, reinterpret_cast(pw)); #endif break; }; // // Copy the creation data. // *pw is either 0 or the number of bytes of creation data, // including *pw. // switch(*pw) { case 0x0000: s << *pw++; break; default: #ifndef UNIX pw += s.Write(pw, *pw) / sizeof(WORD); #else pw += s.Write(pw, *pw) / sizeof(DWORD); #endif break; }; *ppw = pw; return s.WriteError() ? E_OUTOFMEMORY : NOERROR; } // // This is the public function for converting a DLGTEMPLATE to // a DLGTEMPLATEEX. // // Returns: E_OUTOFMEMORY, NOERROR // HRESULT CvtDlgToDlgEx( LPDLGTEMPLATE pTemplate, LPDLGTEMPLATEEX *ppTemplateExOut, int iCharset ) { CDlgTemplateConverter dtc(iCharset); return dtc.DlgToDlgEx(pTemplate, ppTemplateExOut); }