LPSTR
pReadEulaFromFile(
MSIHANDLE hInstall)
{
XTL::AutoProcessHeapPtr<TCHAR> sourceDir;
UINT ret = pMsiGetProperty(hInstall, _T("SourceDir"), &sourceDir, NULL);
if (ERROR_SUCCESS != ret)
{
pMsiLogMessage(
hInstall,
_T("EULACA: MsiGetProperty(SourceDir) failed, error=0x%X"),
ret);
return NULL;
}
//
// EULA from the property EulaFileName
//
XTL::AutoProcessHeapPtr<CHAR> eulaText =
pReadEulaFromFileEx(hInstall, sourceDir, _T("EulaFileName"));
if (NULL == static_cast<LPSTR>(eulaText))
{
//
// try again with EulaFallbackFileName
//
eulaText = pReadEulaFromFileEx(
hInstall, sourceDir, _T("EulaFallbackFileName"));
if (NULL == static_cast<LPSTR>(eulaText))
{
//
// Once more with EulaFallbackFileName2
//
eulaText = pReadEulaFromFileEx(
hInstall, sourceDir, _T("EulaFallbackFileName2"));
}
}
//
// If eulaText is still NULL, every attempt has been failed.
//
if (NULL == static_cast<LPSTR>(eulaText))
{
pMsiLogMessage(
hInstall,
_T("EULACA: EULA files are not available!"));
return NULL;
}
//
// Now we have the EULA Text!
//
return eulaText.Detach();
}
NDASVOL_LINKAGE
HRESULT
NDASVOL_CALL
NdasIsNdasPathA(
IN LPCSTR FilePath)
{
if (IsBadStringPtrA(FilePath, UINT_PTR(-1)))
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"Invalid path, path=%hs\n", FilePath);
return E_INVALIDARG;
}
XTLTRACE2(NdasVolTrace, 4, "NdasIsNdasPathA(%hs)\n", FilePath);
int nChars = MultiByteToWideChar(CP_ACP, 0, FilePath, -1, NULL, 0);
++nChars; // additional terminating NULL char
XTL::AutoProcessHeapPtr<WCHAR> wszFilePath = reinterpret_cast<LPWSTR>(
::HeapAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, nChars * sizeof(WCHAR)));
if (wszFilePath.IsInvalid())
{
return E_OUTOFMEMORY;
}
nChars = MultiByteToWideChar(CP_ACP, 0, FilePath, -1, wszFilePath, nChars);
XTLASSERT(nChars > 0);
return NdasIsNdasPathW(wszFilePath);
}
LPSTR
pReadEulaFromFileEx(
MSIHANDLE hInstall,
LPCTSTR SourceDir,
LPCTSTR PropertyName)
{
TCHAR fullPath[MAX_PATH];
XTL::AutoProcessHeapPtr<TCHAR> eulaFileName;
UINT ret = pMsiGetProperty(hInstall, PropertyName, &eulaFileName, NULL);
if (ERROR_SUCCESS != ret)
{
pMsiLogMessage(
hInstall,
_T("EULACA: MsiGetProperty(%s) failed, error=0x%X"),
PropertyName,
ret);
return NULL;
}
StringCchCopy(fullPath, MAX_PATH, SourceDir);
StringCchCat(fullPath, MAX_PATH, eulaFileName);
pMsiLogMessage(
hInstall,
_T("EULACA: EulaFile=%s"),
fullPath);
//
// RTF file is an ANSI text file not unicode.
// RTF has the CodePage tag inside, so we don't have to
// worry about displaying non-English text.
//
XTL::AutoProcessHeapPtr<CHAR> eulaText = pReadTextFromFile(fullPath);
if (NULL == (LPSTR) eulaText)
{
pMsiLogMessage(
hInstall,
_T("EULACA: ReadTextFromFile(%s) failed, error=0x%X"),
fullPath,
GetLastError());
return NULL;
}
pMsiLogMessage(
hInstall,
_T("EULACA: Read EULA text from %s"),
fullPath);
return eulaText.Detach();
}
LPSTR
pReadTextFromFile(
LPCTSTR szFileName)
{
XTL::AutoFileHandle hFile = CreateFile(
szFileName,
GENERIC_READ,
FILE_SHARE_READ,
NULL,
OPEN_EXISTING,
FILE_ATTRIBUTE_NORMAL | FILE_FLAG_SEQUENTIAL_SCAN,
NULL);
if (INVALID_HANDLE_VALUE == static_cast<HANDLE>(hFile))
{
return NULL;
}
LARGE_INTEGER fileSize;
BOOL fSuccess = GetFileSizeEx(hFile, &fileSize);
if (!fSuccess)
{
return NULL;
}
DWORD cbToRead = fileSize.LowPart;
XTL::AutoProcessHeapPtr<CHAR> lpBuffer = (LPSTR)
::HeapAlloc(
GetProcessHeap(),
HEAP_ZERO_MEMORY,
cbToRead);
if (NULL == static_cast<LPSTR>(lpBuffer))
{
return NULL;
}
DWORD cbRead;
fSuccess = ReadFile(
hFile,
lpBuffer,
cbToRead,
&cbRead,
NULL);
if (!fSuccess)
{
return NULL;
}
return lpBuffer.Detach();
}
NDASVOL_LINKAGE
BOOL
NDASVOL_CALL
NdasIsNdasPathW(
IN LPCWSTR FilePath)
{
CPARAM(IsValidStringPtrW(FilePath, UINT_PTR(-1)));
XTLTRACE2(NdasVolTrace, 4, "NdasIsNdasPathW(%ls)\n", FilePath);
XTL::AutoProcessHeapPtr<TCHAR> mountPoint =
pGetVolumeMountPointForPath(FilePath);
if (mountPoint.IsInvalid())
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
_T("pGetVolumeMountPointForPath(%s) failed, error=0x%X\n"),
FilePath, GetLastError());
return FALSE;
}
XTL::AutoProcessHeapPtr<TCHAR> volumeName =
pGetVolumeDeviceNameForMountPoint(mountPoint);
if (volumeName.IsInvalid())
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
_T("pGetVolumeDeviceNameForMountPoint(%s) failed, error=0x%X\n"),
mountPoint, GetLastError());
return FALSE;
}
// Volume is a \\.\C:
XTL::AutoFileHandle hVolume = ::CreateFileW(
volumeName,
GENERIC_READ,
FILE_SHARE_READ | FILE_SHARE_WRITE,
NULL,
OPEN_EXISTING,
0,
NULL);
if (hVolume.IsInvalid())
{
return FALSE;
}
return NdasIsNdasVolume(hVolume);
}
PSTORAGE_DESCRIPTOR_HEADER
pStorageQueryProperty(
HANDLE hDevice,
STORAGE_PROPERTY_ID PropertyId,
STORAGE_QUERY_TYPE QueryType)
{
STORAGE_PROPERTY_QUERY spquery;
::ZeroMemory(&spquery, sizeof(spquery));
spquery.PropertyId = PropertyId;
spquery.QueryType = QueryType;
DWORD bufferLength = sizeof(STORAGE_DESCRIPTOR_HEADER);
XTL::AutoProcessHeapPtr<STORAGE_DESCRIPTOR_HEADER> buffer =
static_cast<STORAGE_DESCRIPTOR_HEADER*>(
::HeapAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, bufferLength));
if (buffer.IsInvalid())
{
return NULL;
}
DWORD returnedLength;
BOOL fSuccess = ::DeviceIoControl(
hDevice, IOCTL_STORAGE_QUERY_PROPERTY,
&spquery, sizeof(spquery),
buffer, bufferLength,
&returnedLength, NULL);
if (!fSuccess)
{
XTLTRACE_ERR("IOCTL_STORAGE_QUERY_PROPERTY(HEADER) failed.\n");
return NULL;
}
// We only retrived the header, now we reallocate the buffer
// required for the actual query
bufferLength = buffer->Size;
XTL::AutoProcessHeapPtr<STORAGE_DESCRIPTOR_HEADER> newBuffer =
static_cast<STORAGE_DESCRIPTOR_HEADER*>(
::HeapReAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, buffer, bufferLength));
if (newBuffer.IsInvalid())
{
return NULL;
}
// set the buffer with the new buffer
buffer.Detach();
buffer = newBuffer.Detach();
// now we can query the actual property with the proper size
fSuccess = ::DeviceIoControl(
hDevice, IOCTL_STORAGE_QUERY_PROPERTY,
&spquery, sizeof(spquery),
buffer, bufferLength,
&returnedLength, NULL);
if (!fSuccess)
{
XTLTRACE_ERR("IOCTL_STORAGE_QUERY_PROPERTY(DATA) failed.\n");
return NULL;
}
return buffer.Detach();
}
HRESULT
pGetVolumeMountPointForPathW(
__in LPCWSTR Path,
__out LPWSTR* MountPoint)
{
if (NULL == MountPoint)
{
return E_POINTER;
}
*MountPoint = NULL;
// TODO: It is possible to be the path is more than MAX_PATH
// in case of supporting unicode file names up to 65534
DWORD mountPointLength = MAX_PATH;
XTL::AutoProcessHeapPtr<TCHAR> mountPoint =
static_cast<TCHAR*>(
::HeapAlloc(
::GetProcessHeap(),
HEAP_ZERO_MEMORY,
mountPointLength * sizeof(WCHAR)));
if (mountPoint.IsInvalid())
{
return E_OUTOFMEMORY;
}
if (!GetVolumePathName(Path, mountPoint, mountPointLength))
{
HRESULT hr = HRESULT_FROM_WIN32(GetLastError());
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"GetVolumePathName(%ls) failed, hr=0x%X\n",
Path, hr);
return hr;
}
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_INFORMATION,
"Path(%ls) is mounted from %s.\n", Path, mountPoint);
*MountPoint = mountPoint.Detach();
return S_OK;
}
LPTSTR
pGetVolumeInstIdListForDisk(
LPCTSTR DiskInstId)
{
// Disk and volumes are removal relations.
XTL::AutoProcessHeapPtr<TCHAR> VolumeInstIdList;
CONFIGRET ret = pCMGetDeviceIDList(
&VolumeInstIdList,
DiskInstId,
CM_GETIDLIST_FILTER_REMOVALRELATIONS);
if (CR_SUCCESS != ret)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"pCMGetDeviceIDList failed, cret=0x%X\n", ret);
::SetLastError(ConfigRetToWin32Error(ret));
return NULL;
}
return VolumeInstIdList.Detach();
}
LPTSTR
pGetDeviceSymbolicLinkList(
LPCGUID InterfaceClassGuid,
DEVINSTID DevInstId,
ULONG Flags /*= CM_GET_DEVICE_INTERFACE_LIST_PRESENT*/)
{
XTL::AutoProcessHeapPtr<TCHAR> SymbolicLinkList;
CONFIGRET ret = pCMGetDeviceInterfaceList(
&SymbolicLinkList,
const_cast<LPGUID>(InterfaceClassGuid),
DevInstId,
Flags);
if (CR_SUCCESS != ret)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"pCMGetDeviceInterfaceList failed, cret=0x%X\n", ret);
::SetLastError(ConfigRetToWin32Error(ret));
return NULL;
}
return SymbolicLinkList.Detach();
}
//
// Returns the symbolic link name of the disk.
//
// Caller should free the non-null returned pointer
// with HeapFree(GetProcessHeap(),...)
//
LPTSTR
pGetChildDevInstIdsForNdasScsiLocation(
const NDAS_SCSI_LOCATION* NdasScsiLocation)
{
DEVINST NdasScsiDevInst;
if (!pFindNdasScsiDevInst(&NdasScsiDevInst, NdasScsiLocation->SlotNo))
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"FindNdasScsiDevInst failed, error=0x%X\n", GetLastError());
return NULL;
}
TCHAR NdasScsiInstanceId[MAX_DEVICE_ID_LEN];
CONFIGRET ret = ::CM_Get_Device_ID(
NdasScsiDevInst,
NdasScsiInstanceId,
RTL_NUMBER_OF(NdasScsiInstanceId),
0);
if (CR_SUCCESS != ret)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"CM_Get_Device_ID failed, cret=0x%X\n", ret);
return NULL;
}
XTL::AutoProcessHeapPtr<TCHAR> ChildDevInstIdList;
ret = pCMGetDeviceIDList(
&ChildDevInstIdList,
NdasScsiInstanceId,
CM_GETIDLIST_FILTER_BUSRELATIONS);
if (CR_SUCCESS != ret)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"pCMGetDeviceIDList failed, cret=0x%X\n", ret);
::SetLastError(ConfigRetToWin32Error(ret));
return NULL;
}
return ChildDevInstIdList.Detach();
}
LPTSTR
pMsiGetSourcePath(
MSIHANDLE hInstall,
LPCTSTR szFolder,
LPDWORD pcch)
{
XTL::AutoProcessHeapPtr<TCHAR> pszValue;
DWORD cchValue = 0;
UINT msiret = MsiGetSourcePath(hInstall, szFolder, _T(""), &cchValue);
if (ERROR_MORE_DATA == msiret)
{
++cchValue;
pszValue = (LPTSTR) HeapAlloc(
GetProcessHeap(),
0,
cchValue * sizeof(TCHAR));
if (NULL == (LPTSTR) pszValue)
{
return NULL;
}
msiret = MsiGetSourcePath(hInstall, szFolder, pszValue, &cchValue);
}
if (ERROR_SUCCESS != msiret)
{
return NULL;
}
if (NULL != pcch)
{
*pcch = cchValue;
}
return pszValue.Detach();
}
LPTSTR
pMsiGetProperty(
MSIHANDLE hInstall,
LPCTSTR szPropertyName,
LPDWORD pcch)
{
HANDLE hHeap = ::GetProcessHeap();
XTL::AutoProcessHeapPtr<TCHAR> pszValue;
DWORD cchValue = 0;
UINT msiret = MsiGetProperty(hInstall, szPropertyName, _T(""), &cchValue);
if (ERROR_SUCCESS != msiret && ERROR_MORE_DATA != msiret)
{
return NULL;
}
if (ERROR_MORE_DATA == msiret)
{
++cchValue;
pszValue = (LPTSTR) HeapAlloc(GetProcessHeap(), 0, cchValue * sizeof(TCHAR));
if (NULL == (LPTSTR) pszValue)
{
return NULL;
}
msiret = MsiGetProperty(hInstall, szPropertyName, pszValue, &cchValue);
if (ERROR_SUCCESS != msiret)
{
return NULL;
}
}
if (NULL != pcch)
{
*pcch = cchValue;
}
return pszValue.Detach();
}
NDASVOL_LINKAGE
BOOL
NDASVOL_CALL
NdasIsNdasPathA(
IN LPCSTR FilePath)
{
CPARAM(IsValidStringPtrA(FilePath, UINT_PTR(-1)));
XTLTRACE2(NdasVolTrace, 4, "NdasIsNdasPathA(%hs)\n", FilePath);
int nChars = ::MultiByteToWideChar(CP_ACP, 0, FilePath, -1, NULL, 0);
++nChars; // additional terminating NULL char
XTL::AutoProcessHeapPtr<WCHAR> wszFilePath = reinterpret_cast<LPWSTR>(
::HeapAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, nChars * sizeof(WCHAR)));
if (wszFilePath.IsInvalid())
{
::SetLastError(ERROR_OUTOFMEMORY);
return FALSE;
}
nChars = ::MultiByteToWideChar(CP_ACP, 0, FilePath, -1, wszFilePath, nChars);
return NdasIsNdasPathW(wszFilePath);
}
PDRIVE_LAYOUT_INFORMATION_EX
pDiskGetDriveLayoutEx(HANDLE hDevice)
{
DWORD returnedLength; // always returns 0
DWORD bufferLength = sizeof(DRIVE_LAYOUT_INFORMATION_EX);
XTL::AutoProcessHeapPtr<DRIVE_LAYOUT_INFORMATION_EX> buffer =
static_cast<DRIVE_LAYOUT_INFORMATION_EX*>(
::HeapAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, bufferLength));
BOOL fSuccess = ::DeviceIoControl(
hDevice, IOCTL_DISK_GET_DRIVE_LAYOUT_EX,
NULL, 0,
buffer, bufferLength,
&returnedLength, NULL);
while (!fSuccess && ERROR_INSUFFICIENT_BUFFER == ::GetLastError())
{
// To determine the size of output buffer that is required, caller
// should send this IOCTL request in a loop. Every time the
// storage stack rejects the IOCTL with an error message
// indicating that the buffer was too small, caller should double
// the buffer size.
bufferLength += bufferLength;
XTL::AutoProcessHeapPtr<DRIVE_LAYOUT_INFORMATION_EX> newBuffer =
static_cast<DRIVE_LAYOUT_INFORMATION_EX*>(
::HeapReAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, buffer, bufferLength));
if (newBuffer.IsInvalid())
{
// buffer is still valid in case of failure
// buffer will be released on return.
return NULL;
}
// buffer points to the non-valid memory, so invalidate it now
buffer.Detach();
// transfer the data from newBuffer to buffer
buffer = newBuffer.Detach();
// query again
fSuccess = ::DeviceIoControl(
hDevice, IOCTL_DISK_GET_DRIVE_LAYOUT_EX,
NULL, 0,
buffer, bufferLength,
&returnedLength, NULL);
}
// returns the buffer
return buffer.Detach();
}
LPTSTR
pGetDiskForNdasScsiLocationEx(
const NDAS_SCSI_LOCATION* NdasScsiLocation,
BOOL SymbolicLinkOrDevInstId)
{
// Get the child device instances of the NDAS SCSI pdo
XTL::AutoProcessHeapPtr<TCHAR> ChildDevInstIdList =
pGetChildDevInstIdsForNdasScsiLocation(NdasScsiLocation);
// Find the disk of TargetID and LUN for all child device instances
for (LPCTSTR ChildDevInstId = ChildDevInstIdList;
ChildDevInstId && *ChildDevInstId;
ChildDevInstId += ::lstrlen(ChildDevInstId) + 1)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_VERBOSE,
_T("ChildDevInstId:%s\n"), ChildDevInstId);
// Ensure that the child really is present (not ghosted)
DEVINST ChildDevInst;
CONFIGRET ret = ::CM_Locate_DevNode(
&ChildDevInst,
const_cast<DEVINSTID>(ChildDevInstId),
CM_LOCATE_DEVNODE_NORMAL);
if (CR_SUCCESS != ret)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"CM_Locate_DevNode failed, cret=0x%X\n", ret);
continue;
}
// Query the Disk Class Interface, if there are no disk class
// interface, it is not of a disk class.
XTL::AutoProcessHeapPtr<TCHAR> SymLinkList;
ret = pCMGetDeviceInterfaceList(
&SymLinkList,
&DiskClassGuid,
const_cast<DEVINSTID>(ChildDevInstId),
CM_GET_DEVICE_INTERFACE_LIST_PRESENT);
if (CR_SUCCESS != ret)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"pCMGetDeviceInterfaceList failed, cret=0x%X\n", ret);
continue;
}
// Returned list contains the list of the device file names (or
// symbolic links) which we can open with CreateFile for IO_CTLs
for (LPCTSTR DeviceName = SymLinkList;
DeviceName && *DeviceName;
DeviceName += ::lstrlen(DeviceName) + 1)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_VERBOSE,
_T("Device:%s\n"), DeviceName);
XTL::AutoFileHandle hDevice = ::CreateFile(
DeviceName,
GENERIC_READ,
FILE_SHARE_READ | FILE_SHARE_WRITE,
NULL,
OPEN_EXISTING,
0,
NULL);
if (hDevice.IsInvalid())
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
_T("CreateFile(%s) failed, error=0x%X\n"),
DeviceName, GetLastError());
continue;
}
// Query the SCSI Address and compare TargetID and LUN to
// compare them with those of NDAS SCSI location.
SCSI_ADDRESS scsiAddress;
if (!pScsiGetAddress(hDevice, &scsiAddress))
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
_T("GetScsiAddress(%s) failed, error=0x%X\n"),
DeviceName, GetLastError());
continue;
}
if (NdasScsiLocation->TargetID == scsiAddress.TargetId &&
NdasScsiLocation->LUN == scsiAddress.Lun)
{
// We found the target disk, and we create a buffer to
// return. If SymbolicLinkOrDevInstId is non-zero (TRUE),
// we will returns SymbolicLink, otherwise, we will return the DevInstId
if (SymbolicLinkOrDevInstId)
{
DWORD TargetLength = (::lstrlen(DeviceName) + 1) * sizeof(TCHAR);
XTL::AutoProcessHeapPtr<TCHAR> TargetDeviceName =
static_cast<LPTSTR>(
::HeapAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, TargetLength));
if (TargetDeviceName.IsInvalid())
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"HeapAlloc failed, byets=%d\n", TargetLength);
return NULL;
}
::CopyMemory(TargetDeviceName, DeviceName, TargetLength);
return TargetDeviceName.Detach();
}
else
{
DWORD TargetLength = (::lstrlen(ChildDevInstId) + 1) * sizeof(TCHAR);
XTL::AutoProcessHeapPtr<TCHAR> TargetDevInstId =
static_cast<LPTSTR>(
::HeapAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, TargetLength));
if (TargetDevInstId.IsInvalid())
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"HeapAlloc failed, byets=%d\n", TargetLength);
return NULL;
}
::CopyMemory(TargetDevInstId, ChildDevInstId, TargetLength);
return TargetDevInstId.Detach();
}
}
}
}
return NULL;
}
CONFIGRET
pCMGetDeviceIDList(
LPTSTR* RelDevInstIdList,
LPCTSTR DevInstId,
ULONG Flags)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_INFORMATION,
_T("DevInstId=%s,Flags=%08X\n"), DevInstId, Flags);
*RelDevInstIdList = NULL;
ULONG bufferLength;
CONFIGRET ret = ::CM_Get_Device_ID_List_Size(
&bufferLength,
DevInstId,
Flags);
if (CR_SUCCESS != ret)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"CM_Get_Device_ID_List_Size failed with cret=0x%X.\n", ret);
return ret;
}
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_VERBOSE,
"RequiredBufferSize=%d chars\n", bufferLength);
if (0 == bufferLength)
{
TCHAR* empty = static_cast<TCHAR*>(
::HeapAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, 2 * sizeof(TCHAR)));
*RelDevInstIdList = empty;
return CR_SUCCESS;
}
XTL::AutoProcessHeapPtr<TCHAR> buffer = static_cast<TCHAR*>(
::HeapAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, bufferLength * sizeof(TCHAR)));
if (buffer.IsInvalid())
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"HeapAlloc failed, bytes=%d\n", bufferLength * sizeof(TCHAR));
return CR_OUT_OF_MEMORY;
}
ret = ::CM_Get_Device_ID_List(
DevInstId,
buffer,
bufferLength,
Flags);
if (CR_SUCCESS != ret)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"CM_Get_Device_ID_List failed with cret=0x%X.\n", ret);
return ret;
}
*RelDevInstIdList = buffer.Detach();
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_INFORMATION,
_T("RelDevInstIdList=%s\n"), *RelDevInstIdList);
return CR_SUCCESS;
}
HRESULT
pGetVolumeDeviceNameForMountPointW(
__in LPCWSTR VolumeMountPoint,
__out LPWSTR* VolumeDeviceName)
{
// The lpszVolumeMountPoint parameter may be a drive letter with
// appended backslash (\), such as "D:\". Alternatively, it may be
// a path to a volume mount point, again with appended backslash (\),
// such as "c:\mnt\edrive\".
// A reasonable size for the buffer to accommodate the largest possible
// volume name is 50 characters --> wrong 100
HRESULT hr;
XTLASSERT(NULL != VolumeDeviceName);
if (NULL == VolumeDeviceName)
{
return E_POINTER;
}
*VolumeDeviceName = NULL;
const DWORD MAX_VOLUMENAME_LEN = 50;
DWORD volumeDeviceNameLength = MAX_VOLUMENAME_LEN;
XTL::AutoProcessHeapPtr<TCHAR> volumeDeviceName =
static_cast<TCHAR*>(
HeapAlloc(
GetProcessHeap(),
HEAP_ZERO_MEMORY,
volumeDeviceNameLength * sizeof(TCHAR)));
if (volumeDeviceName.IsInvalid())
{
XTLTRACE2(NdasVolTrace, 0,
"HeapAlloc for %d bytes failed.\n", volumeDeviceNameLength);
return E_OUTOFMEMORY;
}
BOOL success = GetVolumeNameForVolumeMountPoint(
VolumeMountPoint,
volumeDeviceName,
volumeDeviceNameLength);
if (!success)
{
hr = HRESULT_FROM_WIN32(GetLastError());
XTLTRACE2(NdasVolTrace, 0,
"GetVolumeNameForVolumeMountPoint(%ls) failed, hr=0x%X\n",
VolumeMountPoint, hr);
return hr;
}
// Volume Name is a format of \\?\Volume{XXXX}\ with trailing backslash
// Volume device name is that of \\.\Volume{XXXX} without trailing backslash
_ASSERTE(_T('\\') == volumeDeviceName[0]);
_ASSERTE(_T('\\') == volumeDeviceName[1]);
_ASSERTE(_T('?') == volumeDeviceName[2]);
_ASSERTE(_T('\\') == volumeDeviceName[3]);
if (_T('\\') == volumeDeviceName[0] &&
_T('\\') == volumeDeviceName[1] &&
_T('?') == volumeDeviceName[2] &&
_T('\\') == volumeDeviceName[3])
{
// replace ? to .
volumeDeviceName[2] = _T('.');
}
// remove trailing backslash
pRemoveTrailingBackslash(volumeDeviceName);
XTLTRACE2(NdasVolTrace, 2,
"VolumeMountPoint(%ls)=>Volume(%ls)\n",
VolumeMountPoint, volumeDeviceName);
*VolumeDeviceName = volumeDeviceName.Detach();
return S_OK;
}
HRESULT
pIsVolumeSpanningNdasDevice(
__in HANDLE hVolume)
{
HRESULT hr;
XTL::AutoProcessHeapPtr<VOLUME_DISK_EXTENTS> extents =
pVolumeGetVolumeDiskExtents(hVolume);
if (extents.IsInvalid())
{
hr = HRESULT_FROM_WIN32(GetLastError());
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"IOCTL_VOLUME_GET_VOLUME_DISK_EXTENTS failed, hr=0x%X\n",
hr);
return hr;
}
for (DWORD i = 0; i < extents->NumberOfDiskExtents; ++i)
{
const DISK_EXTENT* diskExtent = &extents->Extents[i];
XTLTRACE2(NdasVolTrace, 2,
"Disk Number=%d\n", diskExtent->DiskNumber);
DWORD ndasSlotNumber;
hr = pGetNdasSlotNumberFromDiskNumber(
diskExtent->DiskNumber,
&ndasSlotNumber);
if (FAILED(hr))
{
SCSI_ADDRESS scsiAddress = {0};
//
// Since Windows Server 2003, SCSIPORT PDO does not send
// IOCTL_SCSI_MINIPORT down to the stack. Hence we should send
// the IOCTL directly to SCSI controller.
//
XTLTRACE2(NdasVolTrace, 2,
"PhysicalDrive%d does not seem to an NDAS SCSI. Try with the adapter\n",
diskExtent->DiskNumber);
hr = pGetScsiAddressForDiskNumber(
diskExtent->DiskNumber,
&scsiAddress);
if (FAILED(hr))
{
XTLTRACE2(NdasVolTrace, 1,
"Disk %d does not seem to be attached to the SCSI controller.\n",
diskExtent->DiskNumber);
continue;
}
XTLTRACE2(NdasVolTrace, 2,
"SCSI Address (PortNumber=%d,PathId=%d,TargetId=%d,LUN=%d)\n",
scsiAddress.PortNumber, scsiAddress.PathId,
scsiAddress.TargetId, scsiAddress.Lun);
DWORD ndasSlotNumber;
hr = pGetNdasSlotNumberForScsiPortNumber(
scsiAddress.PortNumber,
&ndasSlotNumber);
if (FAILED(hr))
{
XTLTRACE2(NdasVolTrace, 2,
"ScsiPort %d does not seem to an NDAS SCSI.\n",
scsiAddress.PortNumber);
continue;
}
}
XTLTRACE2(NdasVolTrace, 2,
"Detected Disk %d/%d has a NDAS Slot Number=%d (first found only).\n",
i + 1, extents->NumberOfDiskExtents,
ndasSlotNumber);
return S_OK;
}
return E_FAIL;
}
//
// Returns the symbolic link name list of the volume.
// Each entry is null-terminated and the last entry is terminated
// by an additional null character
//
// Caller should free the non-null returned pointer
// with HeapFree(GetProcessHeap(),...)
//
LPTSTR
pGetVolumesForNdasScsiLocation(
const NDAS_SCSI_LOCATION* NdasScsiLocation)
{
// Get the disk instance id of the location
XTL::AutoProcessHeapPtr<TCHAR> DiskInstId =
pGetDiskForNdasScsiLocationEx(NdasScsiLocation, FALSE);
if (DiskInstId.IsInvalid())
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"GetDiskDevInstId failed, error=0x%X\n", GetLastError());
return NULL;
}
// Get the volume instance id list of the disk
XTL::AutoProcessHeapPtr<TCHAR> VolumeInstIdList =
pGetVolumeInstIdListForDisk(DiskInstId);
if (VolumeInstIdList.IsInvalid())
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"GetVolumeInstIdList failed, error=0x%X\n", GetLastError());
return NULL;
}
// Get the volume names of the disk (via interface query)
// Preallocate the buffer up to MAX_PATH
DWORD bufferLength = MAX_PATH * sizeof(TCHAR);
DWORD bufferRemaining = bufferLength;
XTL::AutoProcessHeapPtr<TCHAR> buffer = static_cast<LPTSTR>(
::HeapAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, bufferLength));
LPTSTR bufferNext = static_cast<LPTSTR>(buffer); // direct resource access (non-const)
for (LPCTSTR VolumeInstId = VolumeInstIdList;
VolumeInstId && *VolumeInstId;
VolumeInstId += ::lstrlen(VolumeInstId) + 1)
{
// Actually returned buffer is a list of null-terminated strings
// but we queried for a specific instance id and for the specific
// class, where only one or zero volume name may return.
// So the return type is just a single string.
XTL::AutoProcessHeapPtr<TCHAR> VolumeName =
pGetDeviceSymbolicLinkList(
&GUID_DEVINTERFACE_VOLUME,
const_cast<LPTSTR>(VolumeInstId),
CM_GET_DEVICE_INTERFACE_LIST_PRESENT);
if (VolumeName.IsInvalid())
{
// may not be a volume
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_INFORMATION,
_T("%s is not a volume device\n"), VolumeInstId);
continue;
}
for (LPCTSTR VN = VolumeName; VN && *VN; VN += ::lstrlen(VN) + 1)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_INFORMATION,
_T("VolumeName=%s\n"), VN);
}
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_INFORMATION,
_T("VolumeName=%s\n"), VolumeName);
DWORD volumeNameLength = ::lstrlen(VolumeName);
DWORD bufferRequired = (volumeNameLength + 1) * sizeof(TCHAR);
if (bufferRemaining < bufferRequired)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_INFORMATION,
"Reallocation\n");
XTL::AutoProcessHeapPtr<TCHAR> newBuffer = static_cast<LPTSTR>(
::HeapReAlloc(
::GetProcessHeap(),
HEAP_ZERO_MEMORY,
buffer,
bufferLength + bufferRequired - bufferRemaining));
if (newBuffer.IsInvalid())
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"HeapReAlloc failed, bytes=%d\n",
bufferLength + bufferLength - bufferRemaining);
return NULL;
}
size_t bufferNextOffset =
reinterpret_cast<BYTE*>(bufferNext) -
reinterpret_cast<BYTE*>(*(&buffer));
// discard the old buffer and attach it to the new buffer
buffer.Detach();
buffer = newBuffer.Detach();
bufferNext = reinterpret_cast<TCHAR*>(
reinterpret_cast<BYTE*>(static_cast<LPTSTR>(buffer)) + bufferNextOffset);
}
::CopyMemory(bufferNext, VolumeName, bufferRequired);
bufferNext += volumeNameLength + 1;
bufferRemaining -= bufferRequired;
}
return buffer.Detach();
}
NDASVOL_LINKAGE
BOOL
NDASVOL_CALL
NdasEnumNdasScsiLocationsForVolume(
IN HANDLE hVolume,
NDASSCSILOCATIONENUMPROC EnumProc,
LPVOID Context)
{
CPARAM(!::IsBadCodePtr((FARPROC)EnumProc));
XTL::AutoProcessHeapPtr<VOLUME_DISK_EXTENTS> extents =
pVolumeGetVolumeDiskExtents(hVolume);
if (extents.IsInvalid())
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"IOCTL_VOLUME_GET_VOLUME_DISK_EXTENTS failed, error=0x%X\n",
GetLastError());
return FALSE;
}
for (DWORD i = 0; i < extents->NumberOfDiskExtents; ++i)
{
const DISK_EXTENT* diskExtent = &extents->Extents[i];
SCSI_ADDRESS scsiAddress = {0};
if (!pGetScsiAddressForDiskNumber(diskExtent->DiskNumber, &scsiAddress))
{
XTLTRACE2(NdasVolTrace, 1,
"Disk %d does not seem to be attached to the SCSI controller.\n",
diskExtent->DiskNumber);
continue;
}
XTLTRACE2(NdasVolTrace, 2,
"SCSI Address (PortNumber=%d,PathId=%d,TargetId=%d,LUN=%d)\n",
scsiAddress.PortNumber, scsiAddress.PathId,
scsiAddress.TargetId, scsiAddress.Lun);
DWORD ndasSlotNumber;
if (!pGetNdasSlotNumberForScsiPortNumber(scsiAddress.PortNumber, &ndasSlotNumber))
{
XTLTRACE2(NdasVolTrace, 2,
"ScsiPort %d does not seem to an NDAS SCSI.\n",
scsiAddress.PortNumber);
continue;
}
XTLTRACE2(NdasVolTrace, 2,
"Detected Disk %d/%d has NDAS Slot Number=%d (first found only).\n",
i, extents->NumberOfDiskExtents,
ndasSlotNumber);
NDAS_SCSI_LOCATION ndasScsiLocation = {0};
ndasScsiLocation.SlotNo = ndasSlotNumber;
ndasScsiLocation.TargetID = scsiAddress.TargetId;
ndasScsiLocation.LUN = scsiAddress.Lun;
BOOL fContinue = EnumProc(&ndasScsiLocation, Context);
if (!fContinue)
{
return TRUE;
}
}
return TRUE;
}
CNdasUnitDevice*
CNdasUnitDeviceCreator::CreateUnitDiskDevice()
{
//
// Read DIB
//
// Read DIB should success, even if the unit disk does not contain
// the DIB. If it fails, there should be some communication error.
//
XTL::AutoProcessHeapPtr<NDAS_DIB_V2> pDIBv2;
XTL::AutoProcessHeapPtr<BLOCK_ACCESS_CONTROL_LIST> pBACL;
//
// ReadDIB is to allocate pDIBv2
//
BOOL fSuccess = ReadDIB(&pDIBv2);
// attach to auto heap
if (!fSuccess)
{
XTLTRACE2(NDASSVC_NDASUNITDEVICE, TRACE_LEVEL_ERROR,
"ReadDIB failed, error=0x%X\n", GetLastError());
XTLTRACE2(NDASSVC_NDASUNITDEVICE, TRACE_LEVEL_ERROR,
"Creating unit disk device instance failed.\n");
return _CreateUnknownUnitDiskDevice(NDAS_UNITDEVICE_ERROR_HDD_READ_FAILURE);
}
if(0 != pDIBv2->BACLSize)
{
fSuccess = ReadBACL(&pBACL, pDIBv2->BACLSize);
if (!fSuccess)
{
XTLTRACE2(NDASSVC_NDASUNITDEVICE, TRACE_LEVEL_ERROR,
"ReadBACL failed, error=0x%X\n", GetLastError());
XTLTRACE2(NDASSVC_NDASUNITDEVICE, TRACE_LEVEL_ERROR,
"Creating unit disk device instance failed.\n");
return _CreateUnknownUnitDiskDevice(NDAS_UNITDEVICE_ERROR_HDD_READ_FAILURE);
}
}
NDAS_UNITDEVICE_DISK_TYPE diskType = pGetNdasUnitDiskTypeFromDIBv2(pDIBv2);
if (NDAS_UNITDEVICE_DISK_TYPE_UNKNOWN == diskType)
{
//
// Error! Invalid media type
//
XTLTRACE2(NDASSVC_NDASUNITDEVICE, TRACE_LEVEL_ERROR,
"Media type in DIBv2 is invalid, mediaType=0x%X\n", pDIBv2->iMediaType);
//
// we should create generic unknown unit disk device
//
return _CreateUnknownUnitDiskDevice(NDAS_UNITDEVICE_ERROR_HDD_UNKNOWN_LDTYPE);
}
// return NULL;
LPVOID pAddTargetInfo = NULL;
NDAS_RAID_META_DATA Rmd = {0};
if (NMT_RAID1 == pDIBv2->iMediaType ||
NMT_RAID4 == pDIBv2->iMediaType)
{
//
// These types are not used anymore, however,
// for compatibility reasons, we retain these codes
//
pAddTargetInfo = HeapAlloc(
GetProcessHeap(),
HEAP_ZERO_MEMORY,
sizeof(NDAS_LURN_RAID_INFO_V1));
PNDAS_LURN_RAID_INFO_V1 raidInfo =
static_cast<PNDAS_LURN_RAID_INFO_V1>(pAddTargetInfo);
raidInfo->SectorsPerBit = pDIBv2->iSectorsPerBit;
raidInfo->SectorBitmapStart = m_udinfo.SectorCount.QuadPart - 0x0f00;
raidInfo->SectorInfo = m_udinfo.SectorCount.QuadPart - 0x0002;
raidInfo->SectorLastWrittenSector = m_udinfo.SectorCount.QuadPart - 0x1000;
}
else if (NMT_RAID1R2 == pDIBv2->iMediaType ||
NMT_RAID4R2 == pDIBv2->iMediaType ||
NMT_RAID1R3 == pDIBv2->iMediaType ||
NMT_RAID4R3 == pDIBv2->iMediaType)
{
//
// do not allocate with "new INFO_RAID"
// destructor will delete with "HeapFree"
//
pAddTargetInfo = HeapAlloc(
GetProcessHeap(),
HEAP_ZERO_MEMORY,
sizeof(NDAS_LURN_RAID_INFO_V2));
PNDAS_LURN_RAID_INFO_V2 pIR =
reinterpret_cast<PNDAS_LURN_RAID_INFO_V2>(pAddTargetInfo);
fSuccess = m_devComm.ReadDiskBlock(
reinterpret_cast<PBYTE>(&Rmd),
NDAS_BLOCK_LOCATION_RMD,
1);
if (!fSuccess)
{
XTLTRACE2(NDASSVC_NDASUNITDEVICE, TRACE_LEVEL_ERROR, "Reading RMD failed: ");
XTLTRACE2(NDASSVC_NDASUNITDEVICE, TRACE_LEVEL_ERROR, "Creating unit disk device instance failed.\n");
return _CreateUnknownUnitDiskDevice(NDAS_UNITDEVICE_ERROR_HDD_READ_FAILURE);
}
if (Rmd.Signature != NDAS_RAID_META_DATA_SIGNATURE) {
XTLTRACE2(NDASSVC_NDASUNITDEVICE, TRACE_LEVEL_ERROR, "RMD signature mismatch.");
XTLTRACE2(NDASSVC_NDASUNITDEVICE, TRACE_LEVEL_ERROR, "Creating unit disk device instance failed.\n");
return _CreateUnknownUnitDiskDevice(NDAS_UNITDEVICE_ERROR_HDD_UNKNOWN_LDTYPE);
}
pIR->SectorsPerBit = pDIBv2->iSectorsPerBit;
pIR->nSpareDisk = pDIBv2->nSpareCount;
// To fix: Use RaidSetId and ConfigSetId from NdasOpGetRaidInfo
::CopyMemory(&pIR->RaidSetId, &Rmd.RaidSetId, sizeof(pIR->RaidSetId));
::CopyMemory(&pIR->ConfigSetId, &Rmd.ConfigSetId, sizeof(pIR->ConfigSetId));
}
UINT64 ulUserBlocks = static_cast<UINT64>(pDIBv2->sizeUserSpace);
DWORD ldSequence = pDIBv2->iSequence;
NDAS_LOGICALDEVICE_GROUP ldGroup = {0};
ldGroup.Type = pGetNdasLogicalDeviceTypeFromDIBv2(pDIBv2);
ldGroup.nUnitDevices = pDIBv2->nDiskCount + pDIBv2->nSpareCount;
ldGroup.nUnitDevicesSpare = pDIBv2->nSpareCount;
// ::CopyMemory(&ldGroup.RaidSetId, &Rmd.RaidSetId, sizeof(GUID));
// ::CopyMemory(&ldGroup.ConfigSetId, &Rmd.ConfigSetId, sizeof(GUID));
for(DWORD i=0; i<MAX_NDAS_LOGICALDEVICE_GROUP_MEMBER; i++) {
ldGroup.DeviceHwVersions[i] = pDIBv2->UnitDiskInfos[i].HwVersion;
}
//
// Consistency check for DIB
//
// 1. DIB should contain an entry for this unit device
// wich m_pDevice->GetDeviceId() and m_dwUnitNo;
//
// Otherwise, DIB is invalid and reported as Single
//
for(DWORD i = 0; i < ldGroup.nUnitDevices; i++)
{
CopyMemory(
&ldGroup.UnitDevices[i].DeviceId,
pDIBv2->UnitDisks[i].MACAddr,
sizeof(NDAS_DEVICE_ID));
ldGroup.UnitDevices[i].UnitNo = pDIBv2->UnitDisks[i].UnitNumber;
}
//
// Read CONTENT_ENCRYPT
//
// Read CONTENT_ENCRYPT should success, even if the unit disk does not contain
// the CONTENT_ENCRYPT. If it fails, there should be some communication error.
//
NDAS_CONTENT_ENCRYPT_BLOCK ceb = {0};
NDAS_CONTENT_ENCRYPT ce = {0};
fSuccess = ReadContentEncryptBlock(&ceb);
if (!fSuccess)
{
XTLTRACE2(NDASSVC_NDASUNITDEVICE, TRACE_LEVEL_ERROR,
"ReadContentEncryptBlock failed, error=0x%X\n", GetLastError());
XTLTRACE2(NDASSVC_NDASUNITDEVICE, TRACE_LEVEL_ERROR,
"Creating unit disk device instance failed.\n");
(VOID) ::NdasLogEventError2(EVT_NDASSVC_ERROR_CEB_READ_FAILURE);
return _CreateUnknownUnitDiskDevice(NDAS_UNITDEVICE_ERROR_HDD_READ_FAILURE);
}
UINT uiRet = ::NdasEncVerifyContentEncryptBlock(&ceb);
if (NDASENC_ERROR_CEB_INVALID_SIGNATURE == uiRet)
{
// No Content Encryption
// Safe to ignore
ce.Method = NDAS_CONTENT_ENCRYPT_METHOD_NONE;
}
else if (NDASENC_ERROR_CEB_INVALID_CRC == uiRet)
{
// No Content Encryption
// Safe to ignore
ce.Method = NDAS_CONTENT_ENCRYPT_METHOD_NONE;
}
else if (NDASENC_ERROR_CEB_UNSUPPORTED_REVISION == uiRet)
{
// Error !
(VOID) ::NdasLogEventError2(EVT_NDASSVC_ERROR_CEB_UNSUPPORTED_REVISION, uiRet);
// return NULL;
return _CreateUnknownUnitDiskDevice(NDAS_UNITDEVICE_ERROR_HDD_ECKEY_FAILURE);
}
else if (NDASENC_ERROR_CEB_INVALID_KEY_LENGTH == uiRet)
{
// No Content Encryption
(VOID) ::NdasLogEventError2(EVT_NDASSVC_ERROR_CEB_INVALID_KEY_LENGTH, uiRet);
ce.Method = NDAS_CONTENT_ENCRYPT_METHOD_NONE;
}
else if (ERROR_SUCCESS != uiRet)
{
// No Content Encryption
ce.Method = NDAS_CONTENT_ENCRYPT_METHOD_NONE;
}
else
{
//
// We consider the case that ENCRYPTION is not NONE.
//
if (NDAS_CONTENT_ENCRYPT_METHOD_NONE != ceb.Method)
{
BYTE SysKey[16] = {0};
DWORD cbSysKey = sizeof(SysKey);
uiRet = ::NdasEncGetSysKey(cbSysKey, SysKey, &cbSysKey);
if (ERROR_SUCCESS != uiRet)
{
(VOID) ::NdasLogEventError2(EVT_NDASSVC_ERROR_GET_SYS_KEY, uiRet);
// return NULL;
return _CreateUnknownUnitDiskDevice(NDAS_UNITDEVICE_ERROR_HDD_ECKEY_FAILURE);
}
uiRet = ::NdasEncVerifyFingerprintCEB(SysKey, cbSysKey, &ceb);
if (ERROR_SUCCESS != uiRet)
{
(VOID) ::NdasLogEventError2(EVT_NDASSVC_ERROR_SYS_KEY_MISMATCH, uiRet);
// return NULL;
return _CreateUnknownUnitDiskDevice(NDAS_UNITDEVICE_ERROR_HDD_ECKEY_FAILURE);
}
//
// Create Content Encrypt
//
ce.Method = ceb.Method;
ce.KeyLength = ceb.KeyLength;
ce.Key;
uiRet = ::NdasEncCreateContentEncryptKey(
SysKey,
cbSysKey,
ceb.Key,
ceb.KeyLength,
ce.Key,
sizeof(ce.Key));
if (ERROR_SUCCESS != uiRet)
{
(VOID) ::NdasLogEventError2(EVT_NDASSVC_ERROR_KEY_GENERATION_FAILURE, uiRet);
// return NULL;
return _CreateUnknownUnitDiskDevice(NDAS_UNITDEVICE_ERROR_HDD_ECKEY_FAILURE);
}
}
}
CNdasUnitDiskDevice* pUnitDiskDevice =
new CNdasUnitDiskDevice(
m_pDevice,
m_dwUnitNo,
diskType,
m_udinfo,
ldGroup,
ldSequence,
ulUserBlocks,
pAddTargetInfo,
ce,
pDIBv2,
pBACL);
if (NULL == pUnitDiskDevice)
{
return NULL;
}
// We should detach pDIBv2 from being freeed here
// pUnitDiskDevice will take care of it at dtor
pDIBv2.Detach();
pBACL.Detach();
return pUnitDiskDevice;
}
NDASVOL_LINKAGE
HRESULT
NDASVOL_CALL
NdasEnumNdasLocationsForVolume(
IN HANDLE hVolume,
NDASLOCATIONENUMPROC EnumProc,
LPVOID Context)
{
HRESULT hr;
if (IsBadCodePtr((FARPROC)EnumProc))
{
return E_POINTER;
}
XTL::AutoProcessHeapPtr<VOLUME_DISK_EXTENTS> extents =
pVolumeGetVolumeDiskExtents(hVolume);
if (extents.IsInvalid())
{
hr = HRESULT_FROM_WIN32(GetLastError());
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"IOCTL_VOLUME_GET_VOLUME_DISK_EXTENTS failed, hr=0x%x\n",
hr);
return hr;
}
for (DWORD i = 0; i < extents->NumberOfDiskExtents; ++i)
{
const DISK_EXTENT* diskExtent = &extents->Extents[i];
DWORD ndasSlotNumber;
hr = pGetNdasSlotNumberFromDiskNumber(
diskExtent->DiskNumber,
&ndasSlotNumber);
if (FAILED(hr))
{
SCSI_ADDRESS scsiAddress = {0};
//
// Since Windows Server 2003, SCSIPORT PDO does not send
// IOCTL_SCSI_MINIPORT down to the stack. Hence we should send
// the IOCTL directly to SCSI controller.
//
hr = pGetScsiAddressForDiskNumber(
diskExtent->DiskNumber,
&scsiAddress);
if (FAILED(hr))
{
XTLTRACE2(NdasVolTrace, 1,
"Disk %d does not seem to be attached to the SCSI controller.\n",
diskExtent->DiskNumber);
continue;
}
XTLTRACE2(NdasVolTrace, 2,
"SCSI Address (PortNumber=%d,PathId=%d,TargetId=%d,LUN=%d)\n",
scsiAddress.PortNumber, scsiAddress.PathId,
scsiAddress.TargetId, scsiAddress.Lun);
hr = pGetNdasSlotNumberForScsiPortNumber(
scsiAddress.PortNumber,
&ndasSlotNumber);
if (FAILED(hr))
{
XTLTRACE2(NdasVolTrace, 2,
"ScsiPort %d does not seem to an NDAS SCSI.\n",
scsiAddress.PortNumber);
continue;
}
}
XTLTRACE2(NdasVolTrace, 2,
"Detected Disk %d/%d has NDAS Slot Number=%d (first found only).\n",
i, extents->NumberOfDiskExtents,
ndasSlotNumber);
NDAS_LOCATION ndasScsiLocation = ndasSlotNumber;
//
// EnumProc
// S_OK: continue enumeration
// S_FALSE: returns S_OK to the caller (stop enumeration)
// otherwise E_XXX: returns E_XXX to the caller
//
hr = EnumProc(ndasScsiLocation, Context);
if (FAILED(hr))
{
return hr;
}
else if (S_FALSE == hr)
{
return S_OK;
}
}
return S_OK;
}
HRESULT
pGetScsiAddressForDisk(
__in HANDLE hDisk,
__out PSCSI_ADDRESS ScsiAddress)
{
HRESULT hr;
//
// Query Storage Property
//
XTLTRACE2(NdasVolTrace, 3, "DeviceIoControl(IOCTL_STORAGE_QUERY_PROPERTY)\n");
if (NULL == ScsiAddress)
{
return E_POINTER;
}
XTL::AutoProcessHeapPtr<STORAGE_ADAPTER_DESCRIPTOR> adapterDescriptor =
pStorageQueryAdapterProperty(hDisk);
if (adapterDescriptor.IsInvalid())
{
hr = HRESULT_FROM_WIN32(GetLastError());
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"pStorageQueryAdapterProperty failed, hr=0x%X\n",
hr);
return hr;
}
//
// Ignore non-SCSI device
//
if (BusTypeScsi != adapterDescriptor->BusType)
{
hr = NDASVOL_ERROR_NON_NDAS_VOLUME;
XTLTRACE2(NdasVolTrace, 2, "Ignoring non-scsi bus, hr=0x%X\n", hr);
return hr;
}
//
// Query SCSI Address, given that the physical drive is a SCSI device
//
XTLTRACE2(NdasVolTrace, 3, "DeviceIoControl(IOCTL_SCSI_GET_ADDRESS)\n");
SCSI_ADDRESS scsiAddress = {0};
hr = pScsiGetAddress(hDisk, &scsiAddress);
if (FAILED(hr))
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"pScsiGetAddress failed, hr=0x%X\n",
hr);
hr = NDASVOL_ERROR_NON_NDAS_VOLUME;
return hr;
}
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_INFORMATION,
"SCSIAddress: Len: %d, PortNumber: %d, "
"PathId: %d, TargetId: %d, Lun: %d\n",
(DWORD) scsiAddress.Length,
(DWORD) scsiAddress.PortNumber,
(DWORD) scsiAddress.PathId,
(DWORD) scsiAddress.TargetId,
(DWORD) scsiAddress.Lun);
//
// Return the result
//
*ScsiAddress = scsiAddress;
return S_OK;
}
CONFIGRET
pCMGetDeviceInterfaceList(
LPTSTR* SymbolicLinkNameList,
LPCGUID InterfaceClassGuid,
DEVINSTID DevInstId,
ULONG Flags /*= CM_GET_DEVICE_INTERFACE_LIST_PRESENT*/)
{
*SymbolicLinkNameList = NULL;
ULONG bufferLength;
CONFIGRET ret = ::CM_Get_Device_Interface_List_Size(
&bufferLength,
const_cast<LPGUID>(InterfaceClassGuid),
DevInstId,
Flags);
if (CR_SUCCESS != ret)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"CM_Get_Device_Interface_List_Size failed, cret=0x%X.\n", ret);
return ret;
}
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_VERBOSE,
"RequiredBufferSize=%d chars\n", bufferLength);
if (0 == bufferLength)
{
TCHAR* empty = static_cast<TCHAR*>(
::HeapAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, 2 * sizeof(TCHAR)));
*SymbolicLinkNameList = empty;
return CR_SUCCESS;
}
XTL::AutoProcessHeapPtr<TCHAR> buffer = static_cast<TCHAR*>(
::HeapAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, bufferLength * sizeof(TCHAR)));
if (buffer.IsInvalid())
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"HeapAlloc failed, bytes=%d\n", bufferLength * sizeof(TCHAR));
return CR_OUT_OF_MEMORY;
}
ret = ::CM_Get_Device_Interface_List(
const_cast<LPGUID>(InterfaceClassGuid),
DevInstId,
buffer,
bufferLength,
Flags);
if (CR_SUCCESS != ret)
{
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_ERROR,
"CM_Get_Device_Interface_List failed, cret=%x.\n", ret);
return ret;
}
*SymbolicLinkNameList = buffer.Detach();
XTLTRACE2(NdasVolTrace, TRACE_LEVEL_INFORMATION,
_T("SymbolicLinkNameList=%s\n"), *SymbolicLinkNameList);
return CR_SUCCESS;
}
PVOLUME_DISK_EXTENTS
pVolumeGetVolumeDiskExtents(
HANDLE hVolume)
{
DWORD returnedLength;
DWORD bufferLength = sizeof(VOLUME_DISK_EXTENTS);
XTL::AutoProcessHeapPtr<VOLUME_DISK_EXTENTS> buffer =
static_cast<PVOLUME_DISK_EXTENTS>(
::HeapAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, bufferLength));
if (buffer.IsInvalid())
{
XTLTRACE2_ERR(NdasVolTrace, 0,
"HeapAlloc (%d bytes) failed.\n", bufferLength);
return NULL;
}
BOOL fSuccess = ::DeviceIoControl(
hVolume, IOCTL_VOLUME_GET_VOLUME_DISK_EXTENTS,
NULL, 0,
buffer, bufferLength,
&returnedLength, NULL);
if (!fSuccess && ERROR_MORE_DATA == ::GetLastError())
{
//
// An extent is a contiguous run of sectors on one disk. When the
// number of extents returned is greater than one (1), the error
// code ERROR_MORE_DATA is returned. You should call
// DeviceIoControl again, allocating enough buffer space based on
//
// the value of NumberOfDiskExtents after the first DeviceIoControl call.
bufferLength = sizeof(VOLUME_DISK_EXTENTS) - sizeof(DISK_EXTENT) +
sizeof(DISK_EXTENT) * buffer->NumberOfDiskExtents;
XTL::AutoProcessHeapPtr<VOLUME_DISK_EXTENTS> newBuffer =
static_cast<PVOLUME_DISK_EXTENTS>(
::HeapReAlloc(::GetProcessHeap(), HEAP_ZERO_MEMORY, buffer, bufferLength));
if (newBuffer.IsInvalid())
{
// buffer is still valid in case of failure
// buffer will be released on return.
XTLTRACE2_ERR(NdasVolTrace, 0,
"HeapReAlloc (%d bytes) failed.\n", bufferLength);
return NULL;
}
// buffer points to the non-valid memory, so invalidate it now
buffer.Detach();
// transfer the data from newBuffer to buffer
buffer = newBuffer.Detach();
// query again
fSuccess = ::DeviceIoControl(
hVolume, IOCTL_VOLUME_GET_VOLUME_DISK_EXTENTS,
NULL, 0,
buffer, bufferLength,
&returnedLength, NULL);
}
if (!fSuccess)
{
XTLTRACE2_ERR(NdasVolTrace, 0,
"DeviceIoControl(IOCTL_VOLUME_GET_VOLUME_DISK_EXTENTS) failed.\n");
return NULL;
}
// returns the buffer
return buffer.Detach();
}
