BOOL
WINAPI
NdasDmGetDiskNumbersOfVolume(
HANDLE hVolume,
LPDWORD pDiskNumbers,
DWORD dwDiskNumbers,
LPDWORD lpdwDiskNumbersUsed)
{
BOOL fSuccess(FALSE);
DWORD cbReturned(0);
//
// Prepare Volume Disk Extent Buffer
//
DWORD cbVolumeDiskExtents = sizeof(VOLUME_DISK_EXTENTS) +
MAX_VOL_DISK_EXTS * sizeof(VOLUME_DISK_EXTENTS);
PVOLUME_DISK_EXTENTS pVolumeDiskExtents =
(PVOLUME_DISK_EXTENTS) ::HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, cbVolumeDiskExtents);
if (NULL == pVolumeDiskExtents) {
DPErrorEx(_FT("Memory allication (%d bytes) failed: "), cbVolumeDiskExtents);
return FALSE;
}
//
// Get Volume Disk Extents
//
DPTrace(_FT("DeviceIoControl(IOCTL_VOLUME_GET_VOLUME_DISK_EXTENTS)\n"));
fSuccess = ::DeviceIoControl(
hVolume,
IOCTL_VOLUME_GET_VOLUME_DISK_EXTENTS,
NULL,
0,
pVolumeDiskExtents,
cbVolumeDiskExtents,
&cbReturned,
NULL);
if (!fSuccess) {
DPErrorEx(_FT("DeviceIoControl(IOCTL_VOLUME_GET_VOLUME_DISK_EXTENTS) failed: "));
::HeapFree(::GetProcessHeap(), 0, pVolumeDiskExtents);
return FALSE;
}
//
// usually it returns one disk device
//
*lpdwDiskNumbersUsed = 0;
for (DWORD i = 0; i < pVolumeDiskExtents->NumberOfDiskExtents; ++i) {
DPInfo(_FT("Extents[%d]:: Disk Number: %d, Starting Offset: %d, Extent Length: %d.\n"),
i,
pVolumeDiskExtents->Extents[i].DiskNumber,
pVolumeDiskExtents->Extents[i].StartingOffset,
pVolumeDiskExtents->Extents[i].ExtentLength);
if (i < dwDiskNumbers) {
pDiskNumbers[i] = pVolumeDiskExtents->Extents[i].DiskNumber;
++(*lpdwDiskNumbersUsed);
}
}
::HeapFree(::GetProcessHeap(), 0, pVolumeDiskExtents);
return TRUE;
}
int drvinst(int argc, LPTSTR *argv)
{
typedef enum { SVC_INSTALL, SVC_REMOVE, SVC_REMOVE_PNP } COMMAND_TYPE;
struct { COMMAND_TYPE type; LPCTSTR cmd; int argc; BOOL op; } opts[] =
{
{ SVC_INSTALL, L"install", 3, TRUE},
{ SVC_REMOVE, L"remove", 1, FALSE},
{ SVC_REMOVE_PNP, L"removepnp", 1, FALSE}
};
COMMAND_TYPE CmdType;
const DWORD nopts = RTL_NUMBER_OF(opts);
DWORD i = 0;
for (; i < nopts; ++i) {
if (lstrcmpi(opts[i].cmd, argv[0]) == 0) {
if ((argc - 1) == opts[i].argc ||
(opts[i].op && (argc - 1) >= opts[i].argc))
{
CmdType = opts[i].type;
} else {
_ftprintf(stderr, _T("Invalid command arguments.\n"));
return 254;
}
break;
}
}
if (i == nopts) {
_ftprintf(stderr, _T("Invalid command.\n"));
return 254;
}
if (SVC_INSTALL == CmdType) {
LPTSTR szSourceFilePath = argv[1];
LPTSTR szServiceName = argv[2];
LPTSTR szDisplayName = argv[3];
LPTSTR szLoadOrderGroup = NULL;
if (argc > 4) {
szLoadOrderGroup = argv[4];
}
DPInfo(_FT("Source: %s, ServiceName: %s, DisplayName: %s, LoadOrder: %s"),
szSourceFilePath, szServiceName, szDisplayName, szLoadOrderGroup);
BOOL bUpdated;
BOOL fSuccess = NdasDiInstallOrUpdateDriverService(
szSourceFilePath,
szServiceName,
szDisplayName,
_T(""),
SERVICE_KERNEL_DRIVER,
SERVICE_SYSTEM_START,
SERVICE_ERROR_NORMAL,
szLoadOrderGroup,
NULL,
NULL,
&bUpdated);
if (!fSuccess) {
printErrorText();
return 254;
} else {
if (bUpdated)
{
_ftprintf(stdout,
_T("Driver Service %s updated successfully.\n"), szServiceName);
}
else
{
_ftprintf(stdout,
_T("Driver Service %s installed successfully.\n"), szServiceName);
}
return 0;
}
} else if (SVC_REMOVE == CmdType) {
LPTSTR szServiceName = argv[1];
BOOL fSuccess = NdasDiDeleteService(szServiceName);
if (!fSuccess) {
printErrorText();
return 254;
} else {
_ftprintf(stdout,
_T("Driver Service %s deleted successfully.\n"), szServiceName);
}
} else if (SVC_REMOVE_PNP == CmdType) {
LPTSTR szServiceName = argv[1];
DWORD cRemoved;
BOOL fRebootRequired;
BOOL fSuccess = NdasDiRemoveLegacyDevice(
NULL,
szServiceName,
FALSE,
&cRemoved,
&fRebootRequired,
NULL,
NULL);
if (!fSuccess) {
printErrorText();
return 254;
}
_ftprintf(stdout,
_T("Driver Enum Key (%d) removed successfully.%s\n"),
cRemoved,
fRebootRequired ? _T(" (Reboot required)") : _T(""));
} else {
_ftprintf(stderr, _T("Unknown command.\n"));
return 254;
}
return 0;
}
BOOL
WINAPI
NdasDmGetNdasLogDevSlotNoOfScsiPort(
DWORD dwScsiPortNumber,
LPDWORD lpdwSlotNo)
{
BOOL fSuccess(FALSE);
//
// Make up SCSI Port Name
//
TCHAR szScsiPortName[_MAX_PATH + 1];
HRESULT hr = ::StringCchPrintf(
szScsiPortName, _MAX_PATH + 1,
TEXT("\\\\.\\Scsi%d:"), dwScsiPortNumber);
DPInfo(_FT("SCSI Port Name: %s\n"), szScsiPortName);
//
// Open SCSI Port Device
//
HANDLE hScsiPort = ::CreateFile(
szScsiPortName,
GENERIC_READ | GENERIC_WRITE,
FILE_SHARE_READ | FILE_SHARE_WRITE,
NULL,
OPEN_EXISTING,
FILE_ATTRIBUTE_NORMAL,
NULL);
if (INVALID_HANDLE_VALUE == hScsiPort) {
DPErrorEx(_FT("CreateFile(%s) failed: "), szScsiPortName);
return FALSE;
}
//
// Make up IOCTL In-parameter
// LANSCSIMINIPORT_IOCTL_GET_SLOT_NO to get Logical Device Slot No
//
const DWORD cbHeader = sizeof(SRB_IO_CONTROL);
const DWORD cbData = sizeof(ULONG);
const DWORD cbInBuffer = cbHeader + cbData;
DWORD cbReturned(0);
BYTE lpInBuffer[cbInBuffer];
::ZeroMemory(lpInBuffer, cbInBuffer);
PSRB_IO_CONTROL pSrbIoControl = (PSRB_IO_CONTROL) lpInBuffer;
pSrbIoControl->HeaderLength = cbHeader;
::CopyMemory(pSrbIoControl->Signature, LANSCSIMINIPORT_IOCTL_SIGNATURE, 8);
pSrbIoControl->Timeout = 10;
pSrbIoControl->ControlCode = LANSCSIMINIPORT_IOCTL_GET_SLOT_NO;
pSrbIoControl->Length = cbData;
//
// Get Logical Device Slot No
//
fSuccess = ::DeviceIoControl(
hScsiPort,
IOCTL_SCSI_MINIPORT,
lpInBuffer,
cbInBuffer,
lpInBuffer, // we use the same buffer for output
cbInBuffer,
&cbReturned,
NULL);
if (!fSuccess) {
DPErrorEx(_FT("DeviceIoControl(IOCTL_SCSI_MINIPORT,")
_T("LANSCSIMINIPORT_IOCTL_GET_SLOT_NO) failed: "));
::CloseHandle(hScsiPort);
return FALSE;
}
if (0 != pSrbIoControl->ReturnCode) {
DPError(_FT("DeviceIoControl(IOCTL_SCSI_MINIPORT,")
_T("LANSCSIMINIPORT_IOCTL_GET_SLOT_NO) returned error %d.\n"),
pSrbIoControl->ReturnCode);
::CloseHandle(hScsiPort);
return FALSE;
}
//
// Calculate the slot number offset and retrieve the value
//
ULONG* lpdwSlotNoOut = (ULONG*)(lpInBuffer + cbHeader);
*lpdwSlotNo = *lpdwSlotNoOut;
DPInfo(_FT("NDAS Logical Device Slot: %d\n"), *lpdwSlotNo);
::CloseHandle(hScsiPort);
return TRUE;
}
BOOL
CNdasDeviceComm::GetUnitDeviceInformation(PNDAS_UNITDEVICE_INFORMATION pUnitDevInfo)
{
_ASSERTE(m_bInitialized && "CNdasDeviceComm is not initialized");
_ASSERTE(pUnitDevInfo != NULL);
INT iResult = GetDiskInfo(&m_lspath, m_dwUnitNo);
if (0 != iResult) {
// TODO: LANDISK_ERROR_BADKEY?
DPError(_FT("GetDiskInfo failed with error %d\n"), iResult);
return FALSE;
}
PTARGET_DATA pTargetData = &m_lspath.PerTarget[m_dwUnitNo];
pUnitDevInfo->bLBA = pTargetData->bLBA;
pUnitDevInfo->bLBA48 = pTargetData->bLBA48;
pUnitDevInfo->bPIO = pTargetData->bPIO;
pUnitDevInfo->bDMA = pTargetData->bDma;
pUnitDevInfo->bUDMA = pTargetData->bUDma;
pUnitDevInfo->MediaType = pTargetData->MediaType;
pUnitDevInfo->dwROHosts = pTargetData->NRROHost;
pUnitDevInfo->dwRWHosts = pTargetData->NRRWHost;
pUnitDevInfo->SectorCount = pTargetData->SectorCount;
#ifdef UNICODE
//
// What if FwRev, Model, SerialNo is not null terminated?
// -> solved by terminating null between fields
_ASSERTE(sizeof(pUnitDevInfo->szModel) / sizeof(pUnitDevInfo->szModel[0]) == sizeof(pTargetData->Model));
_ASSERTE(sizeof(pUnitDevInfo->szSerialNo) / sizeof(pUnitDevInfo->szSerialNo[0]) == sizeof(pTargetData->SerialNo));
_ASSERTE(sizeof(pUnitDevInfo->szFwRev) / sizeof(pUnitDevInfo->szFwRev[0]) == sizeof(pTargetData->FwRev));
::MultiByteToWideChar(
CP_ACP, 0,
pTargetData->Model, sizeof(pTargetData->Model),
pUnitDevInfo->szModel, sizeof(pUnitDevInfo->szModel) / sizeof(pUnitDevInfo->szModel[0]));
::MultiByteToWideChar(
CP_ACP, 0,
pTargetData->SerialNo, sizeof(pTargetData->SerialNo),
pUnitDevInfo->szSerialNo, sizeof(pUnitDevInfo->szSerialNo) / sizeof(pUnitDevInfo->szSerialNo[0]));
::MultiByteToWideChar(
CP_ACP, 0,
pTargetData->FwRev, sizeof(pTargetData->FwRev),
pUnitDevInfo->szFwRev, sizeof(pUnitDevInfo->szFwRev) / sizeof(pUnitDevInfo->szFwRev[0]));
#else
_ASSERTE(sizeof(pUnitDevInfo->szModel) == sizeof(pTargetData->Model));
_ASSERTE(sizeof(pUnitDevInfo->szFwRev) == sizeof(pTargetData->FwRev));
_ASSERTE(sizeof(pUnitDevInfo->szSerialNo) == sizeof(pTargetData->SerialNo));
::CopyMemory(pUnitDevInfo->szModel, pTargetData->Model, sizeof(pTargetData->Model));
::CopyMemory(pUnitDevInfo->szFwRev, pTargetData->FwRev, sizeof(pTargetData->FwRev));
::CopyMemory(pUnitDevInfo->szSerialNo, pTargetData->SerialNo, sizeof(pTargetData->SerialNo));
#endif
DPInfo(_FT("Model : %s\n"), pUnitDevInfo->szModel);
DPInfo(_FT("Serial No : %s\n"), pUnitDevInfo->szSerialNo);
DPInfo(_FT("Firmware Rev : %s\n"), pUnitDevInfo->szFwRev);
return TRUE;
}
DWORD
CNdasEventMonitor::
OnTaskStart()
{
BOOL bTerminateThread(FALSE);
// 15 sec = 10,000,000 nanosec
// negative value means relative time
LARGE_INTEGER liDueTime;
liDueTime.QuadPart = - 10 * 1000 * 1000;
BOOL fSuccess = ::SetWaitableTimer(
m_hHeartbeatMonitorTimer,
&liDueTime,
HEARTBEAT_MONITOR_INTERVAL,
NULL,
NULL,
FALSE);
if (!fSuccess) {
DPErrorEx(_FT("Setting waitable timer failed: "));
}
do {
//
// Lock against m_vLogDevice set change
//
this->Lock();
DWORD dwLogDevices = m_vLogDevices.size();
DWORD dwHandles = 3 + 2 * dwLogDevices;
HANDLE* hWaitingHandles = new HANDLE[dwHandles];
hWaitingHandles[0] = m_hTaskTerminateEvent;
hWaitingHandles[1] = m_hLogDeviceSetChangeEvent;
hWaitingHandles[2] = m_hHeartbeatMonitorTimer;
PCNdasLogicalDeviceVector::const_iterator itr = m_vLogDevices.begin();
for (DWORD i = 3; itr != m_vLogDevices.end(); ++itr, ++i) {
PCNdasLogicalDevice pLogDevice = *itr;
hWaitingHandles[i] = pLogDevice->GetDisconnectEvent();
hWaitingHandles[dwLogDevices + i] = pLogDevice->GetAlarmEvent();
}
this->Unlock();
BOOL fSuccess = ::ResetEvent(m_hLogDeviceSetChangeEvent);
_ASSERTE(fSuccess);
BOOL bResetLogDeviceSet(FALSE);
do {
DWORD dwWaitResult = ::WaitForMultipleObjects(
dwHandles,
hWaitingHandles,
FALSE,
INFINITE);
if (WAIT_OBJECT_0 == dwWaitResult) {
//
// Terminate Thread Event
//
bTerminateThread = TRUE;
} else if (WAIT_OBJECT_0 + 1 == dwWaitResult) {
//
// LogicalDeviceSetChange Event
//
bResetLogDeviceSet = TRUE;
} else if (WAIT_OBJECT_0 + 2 == dwWaitResult) {
//
// Heartbeat Monitor Timer Event
//
ximeta::CAutoLock autolock(this);
PCNdasDeviceSet::const_iterator itr = m_hbMonDevices.begin();
m_bIterating = TRUE;
for (; itr != m_hbMonDevices.end();) {
PCNdasDevice pDevice = *itr;
BOOL bDetach = pDevice->OnStatusCheck();
if (bDetach) {
DPInfo(_FT("Detaching device %s from the monitor\n"),
CNdasDeviceId(pDevice->GetDeviceId()).ToString());
itr = m_hbMonDevices.erase(itr);
} else {
++itr;
}
}
m_bIterating = FALSE;
} else if (WAIT_OBJECT_0 + 3 <= dwWaitResult &&
dwWaitResult < WAIT_OBJECT_0 + 3 + dwLogDevices)
{
//
// Disconnect Event
//
DWORD n = dwWaitResult - (WAIT_OBJECT_0 + 3);
PCNdasLogicalDevice pLogDevice = m_vLogDevices[n];
DPInfo(_FT("Disconnect Event from slot %d: %s\n"),
pLogDevice->GetSlot(),
pLogDevice->ToString());
//
// Publish event here
//
// TODO: Publish event here
//
CNdasInstanceManager* pInstMan = CNdasInstanceManager::Instance();
_ASSERTE(NULL != pInstMan);
CNdasEventPublisher* pEventPublisher = pInstMan->GetEventPublisher();
_ASSERTE(NULL != pEventPublisher);
NDAS_LOGICALDEVICE_ID logicalDeviceId = {0};
logicalDeviceId.SlotNo = pLogDevice->GetSlot();
logicalDeviceId.TargetId = 0;
logicalDeviceId.LUN = 0;
(void) pEventPublisher->LogicalDeviceDisconnected(logicalDeviceId);
BOOL fSuccess = ::ResetEvent(pLogDevice->GetDisconnectEvent());
_ASSERTE(fSuccess);
//
// Eject device
//
DPInfo(_FT("Ejecting disconnected logical device\n"));
fSuccess = pLogDevice->Eject();
if (!fSuccess) {
DPErrorEx(_FT("Eject failed: "));
DPError(_FT("Trying to unplug...\n"));
fSuccess = pLogDevice->Unplug();
if (!fSuccess) {
DPErrorEx(_FT("Unplugging failed: "));
}
}
} else if (WAIT_OBJECT_0 + 3 + dwLogDevices <= dwWaitResult &&
dwWaitResult < WAIT_OBJECT_0 + 3 + 2 * dwLogDevices)
{
//
// Alarm Event
//
DWORD n = dwWaitResult - (WAIT_OBJECT_0 + 3 + dwLogDevices);
PCNdasLogicalDevice pLogDevice = m_vLogDevices[n];
ULONG ulStatus;
DPInfo(_FT("Alarm Event from slot %d: %s\n"),
pLogDevice->GetSlot(),
pLogDevice->ToString());
LsBusCtlQueryAlarmStatus(pLogDevice->GetSlot(), &ulStatus);
CNdasInstanceManager* pInstMan = CNdasInstanceManager::Instance();
_ASSERTE(NULL != pInstMan);
CNdasEventPublisher* pEventPublisher = pInstMan->GetEventPublisher();
_ASSERTE(NULL != pEventPublisher);
switch (ulStatus) {
case ALARM_STATUS_NORMAL:
{
DPInfo(_FT("Alarm Normal\n"));
NDAS_LOGICALDEVICE_ID logicalDeviceId = {0};
logicalDeviceId.SlotNo = pLogDevice->GetSlot();
logicalDeviceId.TargetId = 0;
logicalDeviceId.LUN = 0;
(void) pEventPublisher->
LogicalDeviceReconnected(logicalDeviceId);
}
break;
case ALARM_STATUS_START_RECONNECT:
{
DPInfo(_FT("Alarm Start Reconnect\n"));
NDAS_LOGICALDEVICE_ID logicalDeviceId = {0};
logicalDeviceId.SlotNo = pLogDevice->GetSlot();
logicalDeviceId.TargetId = 0;
logicalDeviceId.LUN = 0;
(void) pEventPublisher->
LogicalDeviceReconnecting(logicalDeviceId);
}
break;
case ALARM_STATUS_FAIL_RECONNECT: // obsolete
DPInfo(_FT("Alarm Failed Reconnecting\n"));
break;
default:
DPWarning(_FT("Unknown alarm status: %d\n"), ulStatus);
}
//
// TODO: Publish event here
//
BOOL fSuccess = ::ResetEvent(pLogDevice->GetAlarmEvent());
_ASSERTE(fSuccess);
} else {
_ASSERTE(FALSE);
DPErrorEx(_FT("Wait failed: "));
}
} while (!bResetLogDeviceSet && !bTerminateThread);
delete [] hWaitingHandles;
} while (!bTerminateThread);
fSuccess = ::CancelWaitableTimer(m_hHeartbeatMonitorTimer);
if (!fSuccess) {
DPErrorEx(_FT("Canceling waitable timer failed: "));
}
return 0;
}
PCNdasDevice
CNdasDeviceRegistrar::Register(const NDAS_DEVICE_ID& DeviceId, DWORD dwSlotNo)
{
//
// this will lock this class from here
// and releases the lock when the function returns;
//
ximeta::CAutoLock autolock(this);
DPInfo(_FT("Registering device %s at slot %d\n"),
LPCTSTR(CNdasDeviceId(DeviceId)), dwSlotNo);
// check slot number
if (dwSlotNo < 1 || dwSlotNo > m_dwMaxSlotNo) {
::SetLastError(NDASHLPSVC_ERROR_INVALID_SLOT_NUMBER);
return NULL;
}
// check and see if the slot is occupied
if (m_pbSlotOccupied[dwSlotNo]) {
::SetLastError(NDASHLPSVC_ERROR_SLOT_ALREADY_OCCUPIED);
return NULL;
}
// find an duplicate address
if (NULL != Find(DeviceId)) {
::SetLastError(NDASHLPSVC_ERROR_DUPLICATE_DEVICE_ENTRY);
return NULL;
}
// register
PCNdasDevice pDevice = new CNdasDevice(dwSlotNo, DeviceId);
if (NULL == pDevice) {
// memory allocation failed
// No need to set error here!
return NULL;
}
pDevice->AddRef();
BOOL fSuccess = pDevice->Initialize();
if (!fSuccess) {
// DebugPrintError((ERROR_T("Device initialization failed!")));
pDevice->Release();
return NULL;
}
m_pbSlotOccupied[dwSlotNo] = TRUE;
bool insertResult;
insertResult =
m_deviceSlotMap.insert(DeviceSlotMap::value_type(dwSlotNo, pDevice)).second;
_ASSERTE(insertResult == true);
insertResult =
m_deviceIdMap.insert(DeviceIdMap::value_type(DeviceId, pDevice)).second;
_ASSERTE(insertResult == true);
_ASSERTE(m_deviceSlotMap.size() == m_deviceIdMap.size());
TCHAR szContainer[30];
HRESULT hr = ::StringCchPrintf(szContainer, 30, TEXT("Devices\\%04d"), dwSlotNo);
_ASSERT(SUCCEEDED(hr));
fSuccess = _NdasSystemCfg.SetSecureValueEx(
szContainer,
_T("DeviceId"),
&DeviceId,
sizeof(DeviceId));
if (!fSuccess) {
DPWarningEx(
_FT("Writing registration entry to the registry failed at %s.\n"),
szContainer);
}
//
// During bootstrapping, we do not publish this event
// Bootstrapper will do this later.
//
if (!m_fBootstrapping) {
CNdasEventPublisher* pEventPublisher = pGetNdasEventPublisher();
(VOID) pEventPublisher->DeviceEntryChanged();
}
return pDevice;
}
BOOL CNamedPipeTransport::Send(
LPCVOID lpBuffer, DWORD cbToSend, LPDWORD lpcbSent,
LPOVERLAPPED lpOverlapped, DWORD dwFlags)
{
// AUTOFUNCTRACE();
_ASSERTE(!IsBadReadPtr(lpBuffer, cbToSend));
_ASSERTE(!IsBadWritePtr(lpcbSent, sizeof(DWORD)));
_ASSERTE(
(NULL == lpOverlapped) ||
(!IsBadReadPtr(lpOverlapped, sizeof(OVERLAPPED)) &&
NULL != lpOverlapped->hEvent &&
INVALID_HANDLE_VALUE != lpOverlapped->hEvent));
UNREFERENCED_PARAMETER(dwFlags);
// handling sending zero-byte packet
if (cbToSend == 0) {
*lpcbSent = 0;
if (lpOverlapped) {
BOOL fSuccess = ::SetEvent(lpOverlapped->hEvent);
_ASSERT(fSuccess);
}
DPInfo(_FT("Sending 0 byte ignored\n"));
return TRUE;
}
DPInfo(_FT("Sending %d bytes.\n"), cbToSend);
BOOL fSuccess(FALSE);
DWORD cbCurSent(0), cbCurToSend(cbToSend);
const BYTE* lpCurBuffer = reinterpret_cast<const BYTE*>(lpBuffer);
*lpcbSent = 0;
while (cbCurToSend > 0) {
fSuccess = ::WriteFile(m_hPipe, lpBuffer, cbCurToSend, &cbCurSent, lpOverlapped);
if (!fSuccess && NULL != lpOverlapped && ::GetLastError() != ERROR_IO_PENDING) {
break;
}
if (lpOverlapped) {
// wait until timeout (to prevent indefinite waiting...)
DWORD dwWaitResult = ::WaitForSingleObject(lpOverlapped->hEvent, TRANSMIT_TIMEOUT);
if (dwWaitResult != WAIT_OBJECT_0) {
switch (dwWaitResult) {
case WAIT_TIMEOUT: ::SetLastError(WAIT_TIMEOUT);
case WAIT_ABANDONED: ::SetLastError(WAIT_ABANDONED);
default: break;
}
return FALSE;
}
fSuccess = ::GetOverlappedResult(m_hPipe, lpOverlapped, &cbCurSent, TRUE);
if (!fSuccess && ::GetLastError() != ERROR_IO_PENDING) {
break;
}
}
cbCurToSend -= cbCurSent;
*lpcbSent += cbCurSent;
lpCurBuffer += cbCurSent;
}
DPInfo(_FT("Sent %d bytes.\n"), *lpcbSent);
return fSuccess;
}
BOOL CNamedPipeTransport::Receive(
LPVOID lpBuffer, DWORD cbToReceive, LPDWORD lpcbReceived,
LPOVERLAPPED lpOverlapped, LPDWORD lpdwFlags)
{
// AUTOFUNCTRACE();
_ASSERTE(!IsBadWritePtr(lpBuffer, cbToReceive));
_ASSERTE(!IsBadWritePtr(lpcbReceived, sizeof(DWORD)));
_ASSERTE(NULL == lpOverlapped ||
!IsBadWritePtr(lpOverlapped, sizeof(OVERLAPPED)) &&
NULL != lpOverlapped->hEvent &&
INVALID_HANDLE_VALUE != lpOverlapped->hEvent);
UNREFERENCED_PARAMETER(lpdwFlags);
// handling sending zero-byte packet
if (cbToReceive == 0) {
*lpcbReceived = 0;
if (lpOverlapped) {
BOOL fSuccess = ::SetEvent(lpOverlapped->hEvent);
_ASSERT(fSuccess);
}
return TRUE;
}
// we have to receive by the request size
DPInfo(_FT("Reading %d bytes.\n"), cbToReceive);
BOOL fSuccess(FALSE);
DWORD cbCurReceived(0), cbCurToReceive(cbToReceive);
LPBYTE lpCurBuffer = reinterpret_cast<LPBYTE>(lpBuffer);
*lpcbReceived = 0;
while (cbCurToReceive > 0) {
fSuccess = ::ReadFile(m_hPipe, lpBuffer, cbCurToReceive, &cbCurReceived, lpOverlapped);
if (!fSuccess && NULL != lpOverlapped && ::GetLastError() != ERROR_IO_PENDING) {
break;
}
if (lpOverlapped) {
// wait until timeout (to prevent indefinite waiting...)
DWORD dwWaitResult = ::WaitForSingleObject(lpOverlapped->hEvent, TRANSMIT_TIMEOUT);
if (dwWaitResult != WAIT_OBJECT_0) {
switch (dwWaitResult) {
case WAIT_TIMEOUT: ::SetLastError(WAIT_TIMEOUT);
case WAIT_ABANDONED: ::SetLastError(WAIT_ABANDONED);
default: break;
}
return FALSE;
}
fSuccess = ::GetOverlappedResult(m_hPipe, lpOverlapped, &cbCurReceived, TRUE);
if (!fSuccess && ::GetLastError() != ERROR_IO_PENDING) {
break;
}
}
cbCurToReceive -= cbCurReceived;
*lpcbReceived += cbCurReceived;
lpCurBuffer += cbCurReceived;
}
DPInfo(_FT("Read %d bytes.\n"), *lpcbReceived);
return fSuccess;
}
