Leaked source code of windows server 2003
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/////////////////////////////////////////////////////////////////////
//
// Utils.cpp
//
// General-purpose routines that are project independent.
//
// HISTORY
// t-danmo 96.09.22 Creation.
//
/////////////////////////////////////////////////////////////////////
#include "stdafx.h"
#include "progress.h" // CServiceControlProgress
#include "macros.h" // MFC_TRY/MFC_CATCH
USE_HANDLE_MACROS("FILEMGMT(utils.cpp)")
#ifdef _DEBUG
#define new DEBUG_NEW
#undef THIS_FILE
static char THIS_FILE[] = __FILE__;
#endif
//
// Fusion MFC-based property page
//
HPROPSHEETPAGE MyCreatePropertySheetPage(AFX_OLDPROPSHEETPAGE* psp)
{
PROPSHEETPAGE_V3 sp_v3 = {0};
CopyMemory (&sp_v3, psp, psp->dwSize);
sp_v3.dwSize = sizeof(sp_v3);
return (::CreatePropertySheetPage (&sp_v3));
}
/////////////////////////////////////////////////////////////////////
void
ComboBox_FlushContent(HWND hwndCombo)
{
Assert(IsWindow(hwndCombo));
SendMessage(hwndCombo, CB_RESETCONTENT, 0, 0);
}
/////////////////////////////////////////////////////////////////////
// ComboBox_FFill()
//
// Fill a combo box with the array of string Ids.
//
// Return FALSE if an error occurs (such as stringId not found).
//
BOOL
ComboBox_FFill(
const HWND hwndCombo, // IN: Handle of the combobox
const TStringParamEntry rgzSPE[], // IN: SPE aray zero terminated
const LPARAM lItemDataSelect) // IN: Which item to select
{
CString str;
TCHAR szBuffer[1024];
LRESULT lResult;
Assert(IsWindow(hwndCombo));
Assert(rgzSPE != NULL);
for (int i = 0; rgzSPE[i].uStringId != 0; i++)
{
if (!::LoadString(g_hInstanceSave, rgzSPE[i].uStringId,
OUT szBuffer, LENGTH(szBuffer)))
{
TRACE1("Unable to load string Id=%d.\n", rgzSPE[i].uStringId);
Assert(FALSE && "Unable to load string");
return FALSE;
}
lResult = SendMessage(hwndCombo, CB_ADDSTRING, 0,
reinterpret_cast<LPARAM>(szBuffer));
Report(lResult >= 0);
const WPARAM iIndex = lResult;
lResult = SendMessage(hwndCombo, CB_SETITEMDATA, iIndex,
rgzSPE[i].lItemData);
Report(lResult != CB_ERR);
if (rgzSPE[i].lItemData == lItemDataSelect)
{
SendMessage(hwndCombo, CB_SETCURSEL, iIndex, 0);
}
} // for
return TRUE;
} // ComboBox_FFill()
/////////////////////////////////////////////////////////////////////
// ComboBox_FGetSelectedItemData()
//
// Get the value of the lParam field of the current selected item.
//
// If an error occurs return -1 (CB_ERR).
// Otherwise the value of the selected item.
//
LPARAM
ComboBox_GetSelectedItemData(HWND hwndComboBox)
{
LPARAM l;
Assert(IsWindow(hwndComboBox));
l = SendMessage(hwndComboBox, CB_GETCURSEL, 0, 0);
Report(l != CB_ERR && "Combobox has no item selected");
l = SendMessage(hwndComboBox, CB_GETITEMDATA, l, 0);
Assert(l != CB_ERR && "Cannot extract item data from combobox");
if (l == CB_ERR)
{
Assert(CB_ERR == -1);
return -1;
}
return l;
} // ComboBox_GetSelectedItemData()
/////////////////////////////////////////////////////////////////////
HWND
HGetDlgItem(HWND hdlg, INT nIdDlgItem)
{
Assert(IsWindow(hdlg));
Assert(IsWindow(GetDlgItem(hdlg, nIdDlgItem)));
return GetDlgItem(hdlg, nIdDlgItem);
} // HGetDlgItem()
/////////////////////////////////////////////////////////////////////
void
SetDlgItemFocus(HWND hdlg, INT nIdDlgItem)
{
Assert(IsWindow(hdlg));
Assert(IsWindow(GetDlgItem(hdlg, nIdDlgItem)));
SetFocus(GetDlgItem(hdlg, nIdDlgItem));
}
/////////////////////////////////////////////////////////////////////
void
EnableDlgItem(HWND hdlg, INT nIdDlgItem, BOOL fEnable)
{
Assert(IsWindow(hdlg));
Assert(IsWindow(GetDlgItem(hdlg, nIdDlgItem)));
EnableWindow(GetDlgItem(hdlg, nIdDlgItem), fEnable);
}
/////////////////////////////////////////////////////////////////////
// Enable/disable one or more controls in a dialog.
void
EnableDlgItemGroup(
HWND hdlg, // IN: Parent dialog of the controls
const UINT rgzidCtl[], // IN: Group (array) of control Ids to be enabled (or disabled)
BOOL fEnableAll) // IN: TRUE => We want to enable the controls; FALSE => We want to disable the controls
{
Assert(IsWindow(hdlg));
Assert(rgzidCtl != NULL);
for (const UINT * pidCtl = rgzidCtl; *pidCtl != 0; pidCtl++)
{
EnableWindow(HGetDlgItem(hdlg, *pidCtl), fEnableAll);
}
} // EnableDlgItemGroup()
/////////////////////////////////////////////////////////////////////
// Show/hide one or more controls in a dialog.
void
ShowDlgItemGroup(
HWND hdlg, // IN: Parent dialog of the controls
const UINT rgzidCtl[], // IN: Group (array) of control Ids to be shown (or hidden)
BOOL fShowAll) // IN: TRUE => We want to show the controls; FALSE => We want to hide the controls
{
Assert(IsWindow(hdlg));
Assert(rgzidCtl != NULL);
INT nCmdShow = fShowAll ? SW_SHOW : SW_HIDE;
for (const UINT * pidCtl = rgzidCtl; *pidCtl != 0; pidCtl++)
{
ShowWindow(HGetDlgItem(hdlg, *pidCtl), nCmdShow);
}
} // ShowDlgItemGroup()
/////////////////////////////////////////////////////////////////////
// Str_PchCopyChN()
//
// Copy a string until reaching character chStop or destination buffer full.
//
// RETURNS
// Pointer to the last character of source buffer not copied into destination buffer.
// This may be useful to parse the rest of the source string.
//
// INTERFACE NOTES
// Character chStop is not copied into the destination buffer.
// If cchDstMax==0, the number of characters will not be limited.
//
TCHAR *
Str_PchCopyChN(
TCHAR * szDst, // OUT: Destination buffer
CONST TCHAR * szSrc, // IN: Source buffer
TCHAR chStop, // IN: Character to stop the copying
INT cchDstMax) // IN: Length of the output buffer
{
Assert(szDst != NULL);
Assert(szSrc != NULL);
Assert(cchDstMax >= 0);
while (*szSrc != '\0' && *szSrc != chStop && --cchDstMax != 0)
{
*szDst++ = *szSrc++;
}
*szDst = '\0';
return const_cast<TCHAR *>(szSrc);
} // Str_PchCopyChN()
/////////////////////////////////////////////////////////////////////
// Str_RemoveSubStr()
//
// Scan the source string and remove every occurrence of a
// sub-string.
//
// RETURNS
// Return the number of removals performed.
//
// 580255-2002/03/18 JonN fixed Str_SubstituteStrStr buffer overrun
INT
Str_RemoveSubStr(
WCHAR * szBuf, // IN OUT: Source/Destination buffer
CONST WCHAR * szToken) // IN: Token to remove
{
if (!szBuf || !*szBuf || !szToken || !*szToken)
return 0;
INT cSubstitutions = 0;
size_t cchToken = wcslen(szToken);
TCHAR* pszFound = NULL;
while ( NULL != (pszFound = wcsstr(szBuf,szToken)) )
{
size_t cchBuf = wcslen(szBuf);
TCHAR* pszEndToken = pszFound + cchToken;
size_t cchMove = 1 + (szBuf+cchBuf) - pszEndToken;
wmemmove(pszFound, pszEndToken, cchMove ); // includes trailing NULL
cSubstitutions++;
}
return cSubstitutions;
} // Str_SubstituteStrStr()
/////////////////////////////////////////////////////////////////////
// PchParseCommandLine()
//
// Split a command line into its path to its executable binary and
// its command line arguments. The path to the executable is
// copied into the output buffer.
//
// RETURNS
// Pointer to the next character after path to the executable (Pointer
// may point to an empty string). If an error occurs, return NULL.
//
// FORMATS SUPPORTED
// 1. "c:\\winnt\\foo.exe /bar"
// 2. ""c:\\winnt\\foo.exe" /bar"
// The double quotes around the binary path allow
// the binary path to have spaces.
//
// NTRAID#NTBUG9-580255-2002/03/18 JonN PchParseCommandLine buffer overrun
TCHAR *
PchParseCommandLine(
CONST TCHAR szFullCommand[], // IN: Full command line
TCHAR szBinPath[], // OUT: Path of the executable binary
INT cchBinPathBuf) // IN: Size of the buffer
{
UNREFERENCED_PARAMETER (cchBinPathBuf);
CONST TCHAR * pchSrc = szFullCommand;
TCHAR * pchDst = szBinPath;
BOOL fQuotesFound = FALSE; // TRUE => The binary path is surrounded by quotes (")
Assert(szFullCommand != NULL);
Assert(szBinPath != NULL);
// Skip leading spaces
while (*pchSrc == _T(' '))
pchSrc++;
if (*pchSrc == _T('\"'))
{
fQuotesFound = TRUE;
pchSrc++;
}
while (TRUE)
{
*pchDst = *pchSrc;
if (*pchSrc == _T('\0'))
break;
if (*pchSrc == _T('\"') && fQuotesFound)
{
pchSrc++;
break;
}
if (*pchSrc == _T(' ') && !fQuotesFound)
{
pchSrc++;
break;
}
pchSrc++;
pchDst++;
}
Assert(pchDst - szBinPath < cchBinPathBuf);
*pchDst = _T('\0');
return const_cast<TCHAR *>(pchSrc); // Return character where arguments starts
} // PchParseCommandLine()
/////////////////////////////////////////////////////////////////////
void TrimString(CString& rString)
{
rString.TrimLeft();
rString.TrimRight();
}
/////////////////////////////////////////////////////////////////////
// PargzpszFromPgrsz()
//
// Parse a group of strings into an array of pointers to strings.
// This routine is somewhat similar to CommandLineToArgvW() but
// uses a group of strings instead of a normal string.
//
// RETURN
// Return a pointer to an allocated array of pointers to strings.
// The array of pointers allocated with the new() operator,
// therefore the caller must call ONCE delete() to free memory.
//
// 581272 JonN 2002/04/03 With this change, this function returns an
// array of pointers to strings, but does not allocate the strings
// themselves. pgrsz must not be deleted before the return value.
//
// BACKGROUND
// You need to 'understand' hungarian prefixes to appreciate the
// name of the function.
//
// p Pointer to something
// psz Pointer to string terminated.
// pa Pointer dynamically allocated. For instance, pasz is
// a pointer to an allocated string. The allocation is
// to remind the developper he/she have to free the memory
// when done with the variable.
// rg Array (range). Array (rg) is similar to pointer (p)
// but may point to more than one element.
// rgch is an array of characters while pch points to
// a single character.
// rgz Array of which the last element is zero. The 'last element'
// may be a character, an integer, a pointer or any other
// data type found in the array.
// For instance rgzch would be an array of characters having
// its last character zero -- a string (sz).
// gr Group. This is different than array because indexing
// cannot be used. For instance, a group of strings is
// not the same as an array of strings.
// char grsz[] = "DOS\0WfW\0Win95\0WinNT\0";
// char * rgpsz[] = { "DOS", "WfW", "Win95", "WinNT" };
// char * rgzpsz[] = { "DOS", "WfW", "Win95", "WinNT", NULL };
//
// Now it is time to put all the pieces together.
// pargzpsz = "pa" + "rgz" + "psz"
// pgrsz = "p" + "gr" + "sz"
//
// USAGE
// LPTSTR * pargzpsz;
// pargzpsz = PargzpszFromPgrsz("DOS\0WfW\0Win95\0WinNT\0", OUT &cStringCount);
// delete pargzpsz; // Single delete to free memory
//
// 581272 JonN 2002/04/03 I modified this routine to put minimum trust in
// the pgrsz parameter, which originates in the cfgmgr32 APIs.
//
LPTSTR *
PargzpszFromPgrsz(
CONST LPCTSTR pgrsz, // IN: Pointer to group of strings
INT * pcStringCount) // OUT: OPTIONAL: Count of strings in the stored into returned value
{
if (NULL == pgrsz)
{
ASSERT(FALSE);
return NULL;
}
// Compute how much memory is needed for allocation
int cStringCount = 0;
CONST TCHAR * pchSrc = pgrsz;
while (!IsBadStringPtr(pchSrc, (UINT)-1))
{
if (*pchSrc == _T('\0'))
break;
cStringCount++;
pchSrc += lstrlen(pchSrc)+1;
} // while
// Allocate a single block of memory for all the data
LPTSTR * pargzpsz = new LPTSTR[cStringCount+1];
if (NULL == pargzpsz)
{
Assert(FALSE);
return NULL;
}
ZeroMemory(pargzpsz, (cStringCount+1)*sizeof(LPTSTR));
int iString = 0;
pchSrc = pgrsz;
while (!IsBadStringPtr(pchSrc, (UINT)-1) && iString < cStringCount)
{
pargzpsz[iString++] = (LPTSTR)pchSrc;
pchSrc += lstrlen(pchSrc)+1;
} // for
pargzpsz[cStringCount] = NULL;
if (pcStringCount != NULL)
*pcStringCount = cStringCount;
return pargzpsz;
} // PargzpszFromPgrsz()
/////////////////////////////////////////////////////////////////////
void
ListView_AddColumnHeaders(
HWND hwndListview, // IN: Handle of the listview we want to add columns
const TColumnHeaderItem rgzColumnHeader[]) // IN: Array of column header items
{
RECT rcClient;
INT cxTotalWidth; // Total width of the listview control
LV_COLUMN lvColumn;
INT cxColumn; // Width of the individual column
TCHAR szBuffer[1024];
Assert(IsWindow(hwndListview));
Assert(rgzColumnHeader != NULL);
GetClientRect(hwndListview, OUT &rcClient);
cxTotalWidth = rcClient.right;
lvColumn.pszText = szBuffer;
for (INT i = 0; rgzColumnHeader[i].uStringId != 0; i++)
{
if (!::LoadString(g_hInstanceSave, rgzColumnHeader[i].uStringId,
OUT szBuffer, LENGTH(szBuffer)))
{
TRACE1("Unable to load string Id=%d\n", rgzColumnHeader[i].uStringId);
Assert(FALSE);
continue;
}
lvColumn.mask = LVCF_TEXT;
cxColumn = rgzColumnHeader[i].nColWidth;
if (cxColumn > 0)
{
Assert(cxColumn <= 100);
cxColumn = (cxTotalWidth * cxColumn) / 100;
lvColumn.mask |= LVCF_WIDTH;
lvColumn.cx = cxColumn;
}
INT iColRet = ListView_InsertColumn(hwndListview, i, IN &lvColumn);
Report(iColRet == i);
} // for
} // ListView_AddColumnHeaders()
/////////////////////////////////////////////////////////////////////
int
ListView_InsertItemEx(
HWND hwndListview, // IN: Handle of the listview we want to add item
CONST LV_ITEM * pLvItem) // IN: Pointer to listview item
{
LV_ITEM lvItemT; // Temporary variable
TCHAR szT[1024]; // Temporary buffer
TCHAR * pch;
INT iItem; // Index of the item
Assert(IsWindow(hwndListview));
Assert(pLvItem != NULL);
lvItemT = *pLvItem; // Copy the whole structure
lvItemT.iSubItem = 0;
lvItemT.pszText = szT;
// Copy until the next
pch = Str_PchCopyChN(OUT szT, pLvItem->pszText, '\t', LENGTH(szT));
Assert(pch != NULL);
iItem = ListView_InsertItem(hwndListview, IN &lvItemT);
Report(iItem >= 0);
if (*pch == '\0')
return iItem;
Assert(*pch == '\t');
lvItemT.mask = LVIF_TEXT;
lvItemT.iItem = iItem;
lvItemT.iSubItem = 1;
while (*pch != '\0')
{
pch = Str_PchCopyChN(OUT szT, pch + 1, '\t', LENGTH(szT));
BOOL fRet = ListView_SetItem(hwndListview, IN &lvItemT);
Report(fRet != FALSE);
lvItemT.iSubItem++;
break;
}
return iItem;
} // ListView_InsertItemEx()
/////////////////////////////////////////////////////////////////////
// Display the common dialog to get a filename.
BOOL
UiGetFileName(
HWND hwnd,
TCHAR szFileName[], // OUT: Filename we want to get
INT cchBufferLength) // IN: Length of szFileName buffer
{
OPENFILENAME ofn;
Assert(szFileName != NULL);
Assert(cchBufferLength > 10); // At least 10 characters
TCHAR szBufferT[2048];
::ZeroMemory( szBufferT, sizeof(szBufferT) );
VERIFY(::LoadString(g_hInstanceSave, IDS_OPENFILE_FILTER, szBufferT, LENGTH(szBufferT)));
::ZeroMemory(OUT &ofn, sizeof(ofn));
ofn.lStructSize = sizeof(OPENFILENAME);
ofn.hwndOwner = hwnd;
ofn.hInstance = g_hInstanceSave;
ofn.lpstrFilter = szBufferT;
ofn.nFilterIndex = 1;
ofn.lpstrFile = szFileName;
ofn.nMaxFile = cchBufferLength;
ofn.Flags = OFN_EXPLORER | OFN_HIDEREADONLY;
return GetOpenFileName(&ofn);
} // UiGetFileName()
/////////////////////////////////////////////////////////////////////
// PaszLoadStringPrintf()
//
// Load a string from the resource, and format it and return
// pointer allocated string.
//
// RETURNS
// Pointer to allocated string. Must call LocalFree() when
// done with string.
//
// INTERFACE NOTES
// The format of the resource string uses %1 throuth %99 and
// assumes the arguments are pointers to strings.
//
// If you have an argument other than a string, you can append a
// printf-type within two exclamation marks.
// !s! Insert a string (default)
// !d! Insert a decimal integer
// !u! Insert an unsigned integer
// !x! Insert an hexadecimal integer
//
// HOW TO AVOID BUGS
// To avoid bugs using this routine, I strongly suggest to include
// the format of the string as part of the name of the string Id.
// If you change the format of the string, you should rename
// the string Id to reflect the new format. This will guarantee
// the correct type and number of arguments are used.
//
// EXAMPLES
// IDS_s_PROPERTIES = "%1 Properties"
// IDS_ss_PROPERTIES = "%1 Properties on %2"
// IDS_sus_SERVICE_ERROR = "Service %1 encountered error %2!u! while connecting to %3"
//
// HISTORY
// 96.10.30 t-danmo Creation
//
TCHAR *
PaszLoadStringPrintf(
UINT wIdString, // IN: String Id
va_list arglist) // IN: Arguments (if any)
{
Assert(wIdString != 0);
TCHAR szBufferT[2048];
LPTSTR paszBuffer = NULL; // Pointer to allocated buffer. Caller must call LocalFree() to free it
// Load the string from the resource
VERIFY(::LoadString(g_hInstanceSave, wIdString, szBufferT, LENGTH(szBufferT)));
// Format the string
::FormatMessage(
FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_STRING,
szBufferT,
0,
0,
OUT (LPTSTR)&paszBuffer, // Buffer will be allocated by FormatMessage()
0,
&arglist);
#ifdef DEBUG
if (paszBuffer == NULL)
{
DWORD dw = GetLastError();
Report(FALSE && "FormatMessage() failed.");
}
#endif
return paszBuffer;
} // PaszLoadStringPrintf()
/////////////////////////////////////////////////////////////////////
// LoadStringPrintf()
//
// Load a string from the resources, format it and copy the result string
// into the CString object.
//
// Can also use LoadStringWithInsertions()
// AFX_MANAGE_STATE(AfxGetStaticModuleState())
//
// EXAMPLES
// LoadStrigPrintf(IDS_s_PROPERTIES, OUT &strCaption, szServiceName);
// LoadStrigPrintf(IDS_ss_PROPERTIES, OUT &strCaption, szServiceName, szMachineName);
// LoadStrigPrintf(IDS_sus_SERVICE_ERROR, OUT &strMessage, szServiceName, ::GetLastError(), szMachineName);
//
// ISSUE-2002/03/05-JonN This is a dangerous function
//
void
LoadStringPrintf(
UINT wIdString, // IN: String Id
CString * pString, // OUT: String to receive the characters
...) // IN: Optional arguments
{
Assert(wIdString != NULL);
Assert(pString != NULL);
va_list arglist;
va_start(arglist, pString);
TCHAR * paszBuffer = PaszLoadStringPrintf(wIdString, arglist);
*pString = paszBuffer; // Copy the string into the CString object
LocalFree(paszBuffer);
}
/////////////////////////////////////////////////////////////////////
// SetWindowTextPrintf()
//
// Load a string from the resource, format it and set the window text.
//
// EXAMPLE
// SetWindowText(hwndStatic, IDS_s_PROPERTIES, szObjectName);
//
// HISTORY
// 96.10.30 t-danmo Creation. Core copied from LoadStringPrintf()
//
void
SetWindowTextPrintf(HWND hwnd, UINT wIdString, ...)
{
ASSERT(IsWindow(hwnd));
ASSERT(wIdString != 0);
va_list arglist;
va_start(arglist, wIdString);
TCHAR * paszBuffer = PaszLoadStringPrintf(wIdString, arglist);
if (NULL != paszBuffer) // JonN 5/30/00 PREFIX 110941
SetWindowText(hwnd, paszBuffer); // Set the text of the window
LocalFree(paszBuffer);
} // SetWindowTextPrintf()
#ifdef SNAPIN_PROTOTYPER
const TCHAR rgchHexDigits[] = _T("00112233445566778899aAbBcCdDeEfF");
const TCHAR szSpcTab[] = _T(" \t");
const TCHAR szWhiteSpaces[] = _T(" \t\n\r\f\v");
const TCHAR szDecimalDigits[] = _T("0123456789");
#ifdef UNICODE
#define strchrT wcschr
#else
#define strchrT strchr
#endif
/////////////////////////////////////////////////////////////////////
// FParseInteger()
//
// Parse the source string pchSrc and extract
// its integer value.
//
// RETURNS
// Return TRUE if successful and set uData to integer value
// of the parsed string.
// If not successful (ie, illegal digit or overflow), return FALSE,
// set uData to zero and set nErrCode to error found.
// Field pi.pchStop is always set to the last valid character
// parsed.
//
// INTERFACE NOTES
// Fields pPI->pchSrc and pPI->nFlags are preserved during
// the execution of FParseInteger().
//
BOOL
FParseInteger(INOUT TParseIntegerInfo * pPI)
{
UINT uDataT;
UINT uBase;
UINT iDigit;
UINT cDigitParsed; // Number of digits parsed
BOOL fIsNegative = FALSE;
const TCHAR * pchDigit;
Assert(pPI != NULL);
Assert(pPI->pchSrc != NULL);
pPI->pchStop = pPI->pchSrc;
pPI->nErrCode = PI_errOK; // No error yet
pPI->uData = 0;
uBase = (pPI->nFlags & PI_mskfHexBaseOnly) ? 16 : 10;
cDigitParsed = 0;
// Skip leading blanks
while (*pPI->pchStop ==_T(' '))
pPI->pchStop++;
// Check for a minus sign
if (*pPI->pchStop == _T('-'))
{
if (pPI->nFlags & PI_mskfNoMinusSign)
{
pPI->nErrCode = PI_errMinusSignFound;
return FALSE;
}
fIsNegative = TRUE;
pPI->pchStop++;
}
// Skip leading zeroes
while (*pPI->pchStop == _T('0'))
{
pPI->pchStop++;
cDigitParsed++;
}
// Look for the hexadecimal prefix (0x or 0X)
if (*pPI->pchStop == _T('x') || *pPI->pchStop == _T('X'))
{
if ((pPI->nFlags & PI_mskfAllowHexBase) == 0)
{
pPI->nErrCode = PI_errInvalidInteger;
return FALSE;
}
pPI->pchStop++;
cDigitParsed = 0;
uBase = 16;
} // if
while (*pPI->pchStop != _T('\0'))
{
pchDigit = wcschr(rgchHexDigits, *pPI->pchStop);
if (pchDigit == NULL)
{
if (pPI->nFlags & PI_mskfAllowRandomTail)
break;
// Digit not found while random tail not allowed
pPI->nErrCode = PI_errInvalidInteger;
return FALSE;
} // if
Assert(pchDigit >= rgchHexDigits);
iDigit = (pchDigit - rgchHexDigits) >> 1;
Assert(iDigit <= 0x0F);
if (iDigit >= uBase)
{
// Hex digit found while parsing a decimal string
pPI->nErrCode = PI_errInvalidInteger;
return FALSE;
}
cDigitParsed++;
uDataT = pPI->uData * uBase + iDigit;
if (pPI->uData > ((UINT)-1)/10 || uDataT < pPI->uData)
{
pPI->nErrCode = PI_errIntegerOverflow;
return FALSE;
}
pPI->uData = uDataT;
pPI->pchStop++;
} // while
if ((cDigitParsed == 0) && (pPI->nFlags & PI_mskfNoEmptyString))
{
// Empty String found while not allowed
Assert(pPI->uData == 0);
pPI->nErrCode = PI_errEmptyString;
return FALSE;
}
if (fIsNegative)
{
pPI->uData = -(int)pPI->uData;
}
if (pPI->nFlags & PI_mskfSingleEntry)
{
// Check if there are no more digits at the end of the string
// Only spaces are allowed
while (*pPI->pchStop == _T(' '))
pPI->pchStop++;
if (*pPI->pchStop != _T('\0'))
{
pPI->nErrCode = PI_errInvalidInteger;
return FALSE;
}
}
return TRUE;
} // FParseInteger()
/////////////////////////////////////////////////////////////////////
// FScanf()
//
// Parse a formatted string and extract the values.
// FScanf() behaves like the well known scanf() function but
// has range checking and pattern matching. The wildcard (*)
// may be substituded by "%s" with a NULL pointer.
//
// Return TRUE if successful, otherwise return FALSE
// and set nErrCode to the error found.
//
// Formats supported:
// %d Extract a decimal integer
// %i Extract a generic integer (decimal or hexadecimal)
// %u Extract an unsigned decimal integer (return error if minus sign found)
// %x Force extraction of an hexadecimal integer
// %s Extract a string
// %v Void the spaces and tabs characters
//
// Note:
// Fields sfi.pchSrc and sfi.nFlags are preserved during
// the execution of FScanf().
//
// Example:
// FScanf(&sfi, "%v%s.%s", " \t foobar.txt",
// OUT szName, LENGTH(szName), OUT szExt, LENGTH(szExt));
//
BOOL FScanf(
SCANF_INFO * pSFI, // INOUT: Control structure
const TCHAR * pchFmt, // IN: Format template string
...) // OUT: scanf() arguments
{
va_list arglist;
TParseIntegerInfo pi;
Assert(pSFI != 0);
Assert(pchFmt != NULL);
Assert(pSFI->pchSrc != NULL);
va_start(INOUT arglist, pchFmt);
pSFI->pchSrcStop = pSFI->pchSrc;
pSFI->nErrCode = SF_errOK;
pSFI->cArgParsed = 0;
while (TRUE)
{
switch (*pchFmt++)
{
case 0: // End of string
return TRUE;
case '%':
switch (*pchFmt++)
{
case '%': // "%%"
if (*pSFI->pchSrcStop++ != '%')
{
pSFI->pchSrcStop--;
pSFI->nErrCode = SF_errTemplateMismatch;
return FALSE;
}
break;
case 'v':
while (*pSFI->pchSrcStop == ' ' || *pSFI->pchSrcStop == '\t')
pSFI->pchSrcStop++;
break;
case 'V':
while ((*pSFI->pchSrcStop != '\0') &&
(strchrT(szWhiteSpaces, *pSFI->pchSrcStop) != NULL))
pSFI->pchSrcStop++;
break;
case 'd': // "%d" Decimal integer (signed | unsigned)
case 'u': // "%u" Decimal unsigned integer
case 'i': // "%i" Generic integer (decimal | hexadecimal / signed | unsigned)
case 'x': // "%x" Hexadecimal integer
{
int * p;
pi.nFlags = PI_mskfNoEmptyString | PI_mskfAllowRandomTail;
switch (*(pchFmt-1))
{
case 'u':
pi.nFlags |= PI_mskfNoMinusSign;
break;
case 'i':
pi.nFlags |= PI_mskfAllowHexBase;
break;
case 'x':
pi.nFlags |= PI_mskfHexBaseOnly | PI_mskfNoMinusSign;
} // switch
pi.pchSrc = pSFI->pchSrcStop;
if (!FParseInteger(INOUT &pi))
{
pSFI->pchSrcStop = pi.pchStop;
return FALSE;
} // if
pSFI->pchSrcStop = pi.pchStop;
pSFI->cArgParsed++;
p = (int *)va_arg(arglist, int *);
Assert(p != NULL);
*p = pi.uData;
}
break; // Integer
case 's': // "%s" String
{
// To get a clean string, use the format "%v%s%v"
// which will strip all the spaces and tabs around
// the string.
TCHAR * pchDest; // Destination buffer
int cchDestMax; // Size of destination buffer
TCHAR chEndScan;
const TCHAR * pchEndScan = NULL;
// Find out the ending character(s)
if (*pchFmt == '%')
{
switch (*(pchFmt+1))
{
case 'd':
case 'u':
case 'i':
pchEndScan = szDecimalDigits;
chEndScan = '\0';
break;
case 'v': // %v
pchEndScan = szSpcTab;
chEndScan = *(pchFmt+2);
break;
case 'V': // %V
pchEndScan = szWhiteSpaces;
chEndScan = *(pchFmt+2);
break;
case '%': // %%
chEndScan = '%';
default:
Assert(FALSE); // Ambiguous compound format (not supported anyway!)
} // switch
}
else
{
chEndScan = *pchFmt;
} // if...else
pSFI->cArgParsed++;
pchDest = (TCHAR *)va_arg(arglist, TCHAR *);
if (pchDest != NULL)
{
cchDestMax = va_arg(arglist, int) - 1;
// Verify if the size of destination buffer
// is a valid size.
// Otherwise, this may be the address of the
// next argument
Assert(cchDestMax > 0 && cchDestMax < 5000);
while (cchDestMax-- > 0)
{
if (*pSFI->pchSrcStop == chEndScan)
break;
else if (*pSFI->pchSrcStop == '\0')
break;
else if (pchEndScan != NULL)
{
if (strchrT(pchEndScan, *pSFI->pchSrcStop))
break;
} // if...else
// Copy the character into destination buffer
*pchDest++ = *pSFI->pchSrcStop++;
}
*pchDest = '\0';
} // if
// Skip the characters until reaching either end character
while (TRUE)
{
if (*pSFI->pchSrcStop == chEndScan)
break;
else if (*pSFI->pchSrcStop == '\0')
break;
else if (pchEndScan != NULL)
{
if (strchrT(pchEndScan, *pSFI->pchSrcStop))
break;
} // if...else
pSFI->pchSrcStop++;
} // while
}
break; // "%s"
default:
// Unknown "%?" format
Assert(FALSE);
pSFI->pchSrcStop--;
} // switch
break; // case '%'
default:
if (*(pchFmt-1) != *pSFI->pchSrcStop++)
{
pSFI->pchSrcStop--;
pSFI->nErrCode = SF_errTemplateMismatch;
return FALSE;
}
} // switch
} // while
return TRUE;
} // FScanf()
/////////////////////////////////////////////////////////////////////
// Query the a registry key of type REG_SZ without trowing an exception.
//
BOOL
RegKey_FQueryString(
HKEY hKey,
LPCTSTR pszValueName, // IN: Name of the key
CString& rstrKeyData) // OUT: Value (data) of registry key
{
Assert(hKey != NULL);
Assert(pszValueName != NULL);
TCHAR szBufferT[4096];
DWORD cbBufferLength = sizeof(szBufferT);
DWORD dwType;
DWORD dwErr;
dwErr = ::RegQueryValueEx(
hKey,
pszValueName,
0,
OUT &dwType,
OUT (BYTE *)szBufferT,
INOUT &cbBufferLength);
if ((dwErr == ERROR_SUCCESS) && (dwType == REG_SZ))
{
rstrKeyData = szBufferT; // Copy the string
return TRUE;
}
else
{
rstrKeyData.Empty();
return FALSE;
}
} // RegKey_FQueryString()
#endif // SNAPIN_PROTOTYPER
DWORD DisplayNameHelper(
HWND hwndParent,
BSTR pszMachineName,
BSTR pszServiceName,
DWORD dwDesiredAccess,
SC_HANDLE* phSC,
BSTR* pbstrServiceDisplayName)
{
*phSC = ::OpenSCManager(
pszMachineName,
NULL,
SC_MANAGER_CONNECT);
if (NULL == *phSC)
{
DWORD dwErr = ::GetLastError();
ASSERT( NO_ERROR != dwErr );
return dwErr;
}
SC_HANDLE hService = ::OpenService(
*phSC,
pszServiceName,
dwDesiredAccess | SERVICE_QUERY_CONFIG);
if (NULL == hService)
{
DWORD dwErr = ::GetLastError();
ASSERT( NO_ERROR != dwErr );
::CloseServiceHandle(*phSC);
*phSC = NULL;
return dwErr;
}
union
{
// Service config
QUERY_SERVICE_CONFIG qsc;
BYTE rgbBufferQsc[SERVICE_cbQueryServiceConfigMax];
};
::ZeroMemory(&qsc, max(sizeof(qsc), sizeof(rgbBufferQsc)));
DWORD cbBytesNeeded = 0;
if (!::QueryServiceConfigW(
hService,
OUT &qsc,
max(sizeof(qsc), sizeof(rgbBufferQsc)),
OUT &cbBytesNeeded))
{
DWORD dwErr = ::GetLastError();
ASSERT( NO_ERROR != dwErr );
::CloseServiceHandle(hService);
::CloseServiceHandle(*phSC);
*phSC = NULL;
return dwErr;
}
*pbstrServiceDisplayName = ::SysAllocString(
(qsc.lpDisplayName && qsc.lpDisplayName[0])
? qsc.lpDisplayName
: pszServiceName);
if (NULL == *pbstrServiceDisplayName)
{
::CloseServiceHandle(hService);
::CloseServiceHandle(*phSC);
*phSC = NULL;
return E_OUTOFMEMORY;
}
::CloseServiceHandle(hService);
return NO_ERROR;
}
HRESULT CStartStopHelper::StartServiceHelper(
HWND hwndParent,
BSTR pszMachineName,
BSTR pszServiceName,
DWORD dwNumServiceArgs,
BSTR * lpServiceArgVectors)
{
MFC_TRY;
if ( ( (NULL != pszMachineName)
&& ::IsBadStringPtr(pszMachineName,0x7FFFFFFF))
|| ::IsBadStringPtr(pszServiceName,0x7FFFFFFF))
{
ASSERT(FALSE);
return E_POINTER;
}
if (0 < dwNumServiceArgs)
{
if (::IsBadReadPtr(lpServiceArgVectors,sizeof(lpServiceArgVectors)))
{
ASSERT(FALSE);
return E_POINTER;
}
for (DWORD i = 0; i < dwNumServiceArgs; i++)
{
if ( (NULL != lpServiceArgVectors[i])
&& ::IsBadStringPtr(lpServiceArgVectors[i],0x7FFFFFFF))
{
ASSERT(FALSE);
return E_POINTER;
}
}
}
SC_HANDLE hScManager = NULL;
CComBSTR sbstrServiceDisplayName;
DWORD dwErr = DisplayNameHelper(
hwndParent,
pszMachineName,
pszServiceName,
SERVICE_START,
&hScManager,
&sbstrServiceDisplayName);
if (NO_ERROR != dwErr)
{
(void) DoServicesErrMsgBox(
hwndParent,
MB_OK | MB_ICONSTOP,
dwErr,
IDS_MSG_sss_UNABLE_TO_START_SERVICE,
pszServiceName,
(pszMachineName && pszMachineName[0])
? pszMachineName : (LPCTSTR)g_strLocalMachine,
L"");
}
else
{
dwErr = CServiceControlProgress::S_EStartService(
hwndParent,
hScManager,
pszMachineName,
pszServiceName,
sbstrServiceDisplayName,
dwNumServiceArgs,
(LPCTSTR *)lpServiceArgVectors);
}
if (NULL != hScManager)
(void) ::CloseServiceHandle( hScManager );
switch (dwErr)
{
case CServiceControlProgress::errUserCancelStopDependentServices:
case CServiceControlProgress::errCannotInitialize:
case CServiceControlProgress::errUserAbort:
return S_FALSE;
default:
break;
}
return HRESULT_FROM_WIN32(dwErr);
MFC_CATCH;
}
HRESULT CStartStopHelper::ControlServiceHelper(
HWND hwndParent,
BSTR pszMachineName,
BSTR pszServiceName,
DWORD dwControlCode)
{
MFC_TRY;
if ( ( (NULL != pszMachineName)
&& ::IsBadStringPtr(pszMachineName,0x7FFFFFFF))
|| ::IsBadStringPtr(pszServiceName,0x7FFFFFFF))
{
ASSERT(FALSE);
return E_POINTER;
}
SC_HANDLE hScManager = NULL;
CComBSTR sbstrServiceDisplayName;
DWORD dwDesiredAccess = SERVICE_USER_DEFINED_CONTROL;
UINT idErrorMessageTemplate = IDS_MSG_sss_UNABLE_TO_STOP_SERVICE; // CODEWORK
switch (dwControlCode)
{
case SERVICE_CONTROL_STOP:
idErrorMessageTemplate = IDS_MSG_sss_UNABLE_TO_STOP_SERVICE;
dwDesiredAccess = SERVICE_STOP;
break;
case SERVICE_CONTROL_PAUSE:
idErrorMessageTemplate = IDS_MSG_sss_UNABLE_TO_PAUSE_SERVICE;
dwDesiredAccess = SERVICE_PAUSE_CONTINUE;
break;
case SERVICE_CONTROL_CONTINUE:
idErrorMessageTemplate = IDS_MSG_sss_UNABLE_TO_RESUME_SERVICE;
dwDesiredAccess = SERVICE_PAUSE_CONTINUE;
break;
default:
break;
}
DWORD dwErr = DisplayNameHelper(
hwndParent,
pszMachineName,
pszServiceName,
dwDesiredAccess,
&hScManager,
&sbstrServiceDisplayName);
if (NO_ERROR != dwErr)
{
(void) DoServicesErrMsgBox(
hwndParent,
MB_OK | MB_ICONSTOP,
dwErr,
idErrorMessageTemplate,
pszServiceName,
(pszMachineName && pszMachineName[0])
? pszMachineName : (LPCTSTR)g_strLocalMachine,
L"");
}
else
{
dwErr = CServiceControlProgress::S_EControlService(
hwndParent,
hScManager,
pszMachineName,
pszServiceName,
sbstrServiceDisplayName,
dwControlCode);
}
if (NULL != hScManager)
(void) ::CloseServiceHandle( hScManager );
switch (dwErr)
{
case CServiceControlProgress::errUserCancelStopDependentServices:
case CServiceControlProgress::errCannotInitialize:
case CServiceControlProgress::errUserAbort:
return S_FALSE;
default:
break;
}
return HRESULT_FROM_WIN32(dwErr);
MFC_CATCH;
}