/*++ Copyright (c) 1997-2001 Microsoft Corporation Module Name: driver.c Abstract: This module contains the DriverEntry and other initialization code for the IPSEC module of the Tcpip transport. Author: Sanjay Anand (SanjayAn) 2-January-1997 ChunYe Environment: Kernel mode Revision History: --*/ #include "precomp.h" #ifdef RUN_WPP #include "driver.tmh" #endif #ifdef ALLOC_PRAGMA #pragma alloc_text(INIT, DriverEntry) #pragma alloc_text(INIT, IPSecGeneralInit) #pragma alloc_text(PAGE, IPSecBindToIP) #pragma alloc_text(PAGE, IPSecUnbindFromIP) #pragma alloc_text(PAGE, IPSecFreeConfig) #pragma alloc_text(PAGE, IPSecInitMdlPool) #pragma alloc_text(PAGE, AllocateCacheStructures) #pragma alloc_text(PAGE, FreeExistingCache) #pragma alloc_text(PAGE, FreePatternDbase) #pragma alloc_text(PAGE, OpenRegKey) #pragma alloc_text(PAGE, GetRegDWORDValue) #pragma alloc_text(PAGE, IPSecCryptoInitialize) #pragma alloc_text(PAGE, IPSecCryptoDeinitialize) #endif NTSTATUS DriverEntry( IN PDRIVER_OBJECT DriverObject, IN PUNICODE_STRING RegistryPath ) /*++ Routine Description: This routine performs initialization of the IPSEC module. It creates the device object for the transport provider and performs other driver initialization. Arguments: DriverObject - Pointer to driver object created by the system. RegistryPath - The name of IPSEC's node in the registry. Return Value: The function value is the final status from the initialization operation. --*/ { PDEVICE_OBJECT deviceObject = NULL; WCHAR deviceNameBuffer[] = DD_IPSEC_DEVICE_NAME; WCHAR symbolicLinkBuffer[] = DD_IPSEC_SYM_NAME; UNICODE_STRING symbolicLinkName; UNICODE_STRING deviceNameUnicodeString; NTSTATUS status; NTSTATUS status1; //DbgBreakPoint(); // WPP tracing // WPP_INIT_TRACING(DriverObject, RegistryPath); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Entering DriverEntry")); // // Init g_ipsec structure and read reg keys. // IPSecZeroMemory(&g_ipsec, sizeof(g_ipsec)); // // Create the device - do we need a device at all? // // Setup the handlers. // // // Initialize the driver object with this driver's entry points. // g_ipsec.IPSecDriverObject = DriverObject; IPSecReadRegistry(); DriverObject->MajorFunction [IRP_MJ_CREATE] = DriverObject->MajorFunction [IRP_MJ_CLOSE] = DriverObject->MajorFunction [IRP_MJ_CLEANUP] = DriverObject->MajorFunction [IRP_MJ_INTERNAL_DEVICE_CONTROL] = DriverObject->MajorFunction [IRP_MJ_DEVICE_CONTROL] = IPSecDispatch; DriverObject->DriverUnload = IPSecUnload; RtlInitUnicodeString (&deviceNameUnicodeString, deviceNameBuffer); status = IoCreateDevice( DriverObject, 0, // DeviceExtensionSize &deviceNameUnicodeString, // DeviceName FILE_DEVICE_NETWORK, // DeviceType FILE_DEVICE_SECURE_OPEN, // DeviceCharacteristics FALSE, // Exclusive &deviceObject); // *DeviceObject if (!NT_SUCCESS (status)) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to create device: %lx", status)); LOG_EVENT( DriverObject, EVENT_IPSEC_CREATE_DEVICE_FAILED, 1, 1, &deviceNameUnicodeString.Buffer, 0, NULL); goto err; } deviceObject->Flags |= DO_BUFFERED_IO; IPSecDevice = deviceObject; RtlInitUnicodeString (&symbolicLinkName, symbolicLinkBuffer); status = IoCreateSymbolicLink(&symbolicLinkName, &deviceNameUnicodeString); if (!NT_SUCCESS (status)) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to create symbolic link: %lx", status)); LOG_EVENT( DriverObject, EVENT_IPSEC_CREATE_DEVICE_FAILED, 2, 1, &deviceNameUnicodeString.Buffer, 0, NULL); IoDeleteDevice(DriverObject->DeviceObject); goto err; } // // General structs init here. // Allocates the SA Table etc. // status = IPSecGeneralInit(); if (!NT_SUCCESS (status)) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to init general structs: %lx", status)); // // Free the general structs and SA Table etc. // status1 = IPSecGeneralFree(); if (!NT_SUCCESS (status1)) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to free config: %lx", status1)); } LOG_EVENT( DriverObject, EVENT_IPSEC_NO_RESOURCES_FOR_INIT, 1, 0, NULL, 0, NULL); IoDeleteSymbolicLink(&symbolicLinkName); IoDeleteDevice(DriverObject->DeviceObject); goto err; } // // Wait for TCP/IP to load and call IOCTL_IPSEC_SET_TCPIP_STATUS where we // would finish the initialization. // status = STATUS_SUCCESS; IPSEC_DEBUG(LL_A, DBF_LOAD, ("Exiting DriverEntry; SUCCESS")); err: return status; } VOID IPSecUnload( IN PDRIVER_OBJECT DriverObject ) /*++ Routine Description: Called when the driver is unloaded. Arguments: DriverObject Return Value: None --*/ { UNICODE_STRING IPSecLinkName; KIRQL OldIrq; KIRQL kIrql; NTSTATUS status; INT class; IPSEC_DEBUG(LL_A, DBF_LOAD, ("Entering IPSecUnload")); // // Set IPSEC_DRIVER_UNLOADING bit. // IPSEC_DRIVER_UNLOADING() = TRUE; AcquireWriteLock(&g_ipsec.SADBLock,&kIrql); if (g_ipsec.BootStatefulHT){ IPSecFreeMemory(g_ipsec.BootStatefulHT); g_ipsec.BootStatefulHT = NULL; } if (g_ipsec.BootBufferPool){ IPSecFreeMemory(g_ipsec.BootBufferPool); g_ipsec.BootBufferPool = NULL; } if (g_ipsec.BootExemptList){ IPSecFreeMemory(g_ipsec.BootExemptList); g_ipsec.BootExemptList = NULL; } ReleaseWriteLock(&g_ipsec.SADBLock, kIrql); // // Stop the reaper timer. // IPSecStopTimer(&g_ipsec.ReaperTimer); // // Stop the EventLog timer. // IPSecStopTimer(&g_ipsec.EventLogTimer); // // Complete the Acquire Irp with error status // if (g_ipsec.AcquireInfo.Irp) { IPSEC_DEBUG(LL_A, DBF_ACQUIRE, ("Unload: Completing Irp..")); if (g_ipsec.AcquireInfo.InMe) { IoAcquireCancelSpinLock(&g_ipsec.AcquireInfo.Irp->CancelIrql); IPSecAcquireIrpCancel(NULL, g_ipsec.AcquireInfo.Irp); } } // // Stop timers for all SAs (of all states) // IPSecStopSATimers(); if (g_ipsec.ShimFunctions.pCleanupRoutine) { (g_ipsec.ShimFunctions.pCleanupRoutine)(); } // // Wait for all timers to clear before going further // while (IPSEC_GET_VALUE(g_ipsec.NumTimers) != 0) { IPSEC_DELAY_EXECUTION(); } // // Cleanup any larval SAs // AcquireWriteLock(&g_ipsec.SADBLock, &kIrql); ACQUIRE_LOCK(&g_ipsec.AcquireInfo.Lock, &OldIrq); IPSecFlushLarvalSAList(); IPSecFlushSAExpirations(); RELEASE_LOCK(&g_ipsec.AcquireInfo.Lock, OldIrq); ReleaseWriteLock(&g_ipsec.SADBLock, kIrql); // // Free the SA Table. // status = IPSecFreeConfig(); if (!NT_SUCCESS (status)) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to free config: %lx", status)); } // // Free the MDL pools and run down all buffered packets. // status = IPSecQuiesce(); if (!NT_SUCCESS (status)) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to reach quiescent state: %lx", status)); } AcquireWriteLock(&g_ipsec.SADBLock, &kIrql); ASSERT (gpParserIfEntry == NULL); FlushAllParserEntries(); ReleaseWriteLock(&g_ipsec.SADBLock, kIrql); // // Destroy timer structures // ACQUIRE_LOCK(&g_ipsec.TimerLock, &kIrql); for (class = 0; class < IPSEC_CLASS_MAX; class++) { ASSERT(g_ipsec.TimerList[class].TimerCount == 0); IPSecFreeMemory(g_ipsec.TimerList[class].pTimers); } RELEASE_LOCK(&g_ipsec.TimerLock, kIrql); IPSecCryptoDeinitialize(); #if GPC IPSecGpcDeinitialize(); #endif RtlInitUnicodeString(&IPSecLinkName, DD_IPSEC_SYM_NAME); IoDeleteSymbolicLink(&IPSecLinkName); WPP_CLEANUP(DriverObject); IoDeleteDevice(DriverObject->DeviceObject); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Exiting IPSecUnload")); } NTSTATUS IPSecDispatch( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp ) /*++ Routine Description: Dispatch Routine for the driver. Gets the current irp stack location, validates the parameters and routes the calls Arguments: DeviceObject Irp Return Value: Status as returned by the worker functions --*/ { PIO_STACK_LOCATION irpStack; PVOID pvIoBuffer; LONG inputBufferLength; LONG outputBufferLength; ULONG ioControlCode; NTSTATUS status = STATUS_SUCCESS; LONG dwSize = 0; PAGED_CODE(); IPSEC_DEBUG(LL_A, DBF_IOCTL, ("Entering IPSecDispath")); Irp->IoStatus.Status = status; Irp->IoStatus.Information = 0; // // Get a pointer to the current location in the Irp. This is where // the function codes and parameters are located. // irpStack = IoGetCurrentIrpStackLocation(Irp); // // Get the pointer to the input/output buffer and its length. // pvIoBuffer = Irp->AssociatedIrp.SystemBuffer; inputBufferLength = irpStack->Parameters.DeviceIoControl.InputBufferLength; outputBufferLength = irpStack->Parameters.DeviceIoControl.OutputBufferLength; switch (irpStack->MajorFunction) { case IRP_MJ_CREATE: { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IRP_MJ_CREATE")); break; } case IRP_MJ_CLOSE: { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IRP_MJ_CLOSE")); break; } case IRP_MJ_DEVICE_CONTROL: { ioControlCode = irpStack->Parameters.DeviceIoControl.IoControlCode; IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IRP_MJ_DEVICE_CONTROL: %lx", ioControlCode)); if (ioControlCode != IOCTL_IPSEC_SET_TCPIP_STATUS) { if (IPSEC_DRIVER_IS_INACTIVE()) { status = STATUS_INVALID_DEVICE_STATE; break; } if (!IPSecCryptoInitialize()) { status = STATUS_CRYPTO_SYSTEM_INVALID; break; } } IPSEC_INCREMENT(g_ipsec.NumIoctls); switch (ioControlCode) { case IOCTL_IPSEC_ADD_FILTER: { PIPSEC_ADD_FILTER pAddFilter = (PIPSEC_ADD_FILTER)pvIoBuffer; IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IOCTL_IPSEC_ADD_FILTER")); dwSize = sizeof(IPSEC_ADD_FILTER); if (inputBufferLength < dwSize) { status = STATUS_BUFFER_TOO_SMALL; break; } // // Check the size of the entry // if (pAddFilter->NumEntries == 0) { status = STATUS_SUCCESS; } else { dwSize = FIELD_OFFSET(IPSEC_ADD_FILTER, pInfo[0]) + pAddFilter->NumEntries * sizeof(IPSEC_FILTER_INFO); if (dwSize < FIELD_OFFSET(IPSEC_ADD_FILTER, pInfo[0]) || inputBufferLength < dwSize) { status = STATUS_BUFFER_TOO_SMALL; IPSEC_DEBUG(LL_A, DBF_IOCTL, ("returning: %lx", status)); break; } status = IPSecAddFilter(pAddFilter); } break; } case IOCTL_IPSEC_DELETE_FILTER: { PIPSEC_DELETE_FILTER pDelFilter = (PIPSEC_DELETE_FILTER)pvIoBuffer; IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IOCTL_IPSEC_DELETE_FILTER")); dwSize = sizeof(IPSEC_DELETE_FILTER); if (inputBufferLength < dwSize) { status = STATUS_BUFFER_TOO_SMALL; break; } // // Check the size of the entry // if (pDelFilter->NumEntries == 0) { status = STATUS_SUCCESS; } else { dwSize = FIELD_OFFSET(IPSEC_DELETE_FILTER, pInfo[0]) + pDelFilter->NumEntries * sizeof(IPSEC_FILTER_INFO); if (dwSize < FIELD_OFFSET(IPSEC_DELETE_FILTER, pInfo[0]) || inputBufferLength < dwSize) { status = STATUS_BUFFER_TOO_SMALL; break; } status = IPSecDeleteFilter(pDelFilter); } break; } case IOCTL_IPSEC_ENUM_SAS: { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IOCTL_IPSEC_ENUM_SAS")); dwSize = sizeof(IPSEC_ENUM_SAS); // // Output/Input in the same buffer at MdlAddress // // This functions accesses Irp->MdlAddress // and checks if it is NULL too. status = IPSecEnumSAs(Irp, &dwSize); break; } case IOCTL_IPSEC_ENUM_FILTERS: { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IOCTL_IPSEC_ENUM_FILTERS")); dwSize = sizeof(IPSEC_ENUM_FILTERS); // // Output/Input in the same buffer at MdlAddress // // This functions accesses Irp->MdlAddress // and checks if it is NULL too. status = IPSecEnumFilters(Irp, &dwSize); break; } case IOCTL_IPSEC_QUERY_STATS: { // // The minimum size is without any Keys // IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IOCTL_IPSEC_QUERY_STATS")); dwSize = sizeof(IPSEC_QUERY_STATS); if (outputBufferLength < dwSize) { status = STATUS_BUFFER_TOO_SMALL; break; } *((PIPSEC_QUERY_STATS)pvIoBuffer) = g_ipsec.Statistics; status = STATUS_SUCCESS; break; } case IOCTL_IPSEC_ADD_SA: { // // Adds the SA to the relevant database. // Typically used to add outbound SAs to the DB. // IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IOCTL_IPSEC_ADD_SA")); // // The minimum size is without any Keys // dwSize = IPSEC_ADD_SA_NO_KEY_SIZE; if (inputBufferLength < dwSize) { status = STATUS_BUFFER_TOO_SMALL; break; } status = IPSecAddSA((PIPSEC_ADD_SA)pvIoBuffer, inputBufferLength); ASSERT(status != STATUS_PENDING); if (outputBufferLength >= sizeof(NTSTATUS)) { (*(NTSTATUS *)pvIoBuffer) = status; dwSize = sizeof(NTSTATUS); } else { dwSize = 0; } status = STATUS_SUCCESS; break; } case IOCTL_IPSEC_UPDATE_SA: { // // This completes the negotiation kicked off via the Acquire. // // Adds the SA to the relevant database. // Typically used to complete inbound SA acquisitions. // IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IOCTL_IPSEC_UPDATE_SA")); // // The minimum size is without any Keys // dwSize = IPSEC_UPDATE_SA_NO_KEY_SIZE; if (inputBufferLength < dwSize) { status = STATUS_BUFFER_TOO_SMALL; break; } status = IPSecUpdateSA((PIPSEC_UPDATE_SA)pvIoBuffer, inputBufferLength); ASSERT(status != STATUS_PENDING); if (outputBufferLength >= sizeof(NTSTATUS)) { (*(NTSTATUS *)pvIoBuffer)=status; dwSize = sizeof(NTSTATUS); } else { dwSize = 0; } status = STATUS_SUCCESS; break; } case IOCTL_IPSEC_EXPIRE_SA: { // // Deref the particular SA - delete when ref cnt drops to 0. // IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IOCTL_IPSEC_EXPIRE_SA")); dwSize = sizeof(IPSEC_EXPIRE_SA); if (inputBufferLength < dwSize) { status = STATUS_BUFFER_TOO_SMALL; break; } status = IPSecExpireSA((PIPSEC_EXPIRE_SA)pvIoBuffer); break; } case IOCTL_IPSEC_GET_SPI: { // // returns the SPI for an inbound SA // IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IOCTL_IPSEC_GET_SPI")); dwSize = sizeof(IPSEC_GET_SPI); if (outputBufferLength < dwSize) { status = STATUS_BUFFER_TOO_SMALL; break; } status = IPSecGetSPI((PIPSEC_GET_SPI)pvIoBuffer); break; } case IOCTL_IPSEC_POST_FOR_ACQUIRE_SA: { // // The SAAPI client posts a request that we complete when // an SA needs to be initialized or updated (due to // re-key). // We keep the Irp around until we need an SA to be // negotiated. // IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IPSEC_POST_FOR_ACQUIRE_SA")); dwSize = sizeof(IPSEC_POST_FOR_ACQUIRE_SA); if (outputBufferLength < dwSize) { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IPSEC_POST_FOR_ACQUIRE_SA: bad size: dwSize: %lx, input: %lx", dwSize, inputBufferLength)); status = STATUS_BUFFER_TOO_SMALL; break; } Irp->IoStatus.Status = STATUS_PENDING; status = IPSecHandleAcquireRequest( Irp, (PIPSEC_POST_FOR_ACQUIRE_SA)pvIoBuffer); if (status == STATUS_PENDING) { IPSEC_DECREMENT(g_ipsec.NumIoctls); return status; } break; } case IOCTL_IPSEC_QUERY_EXPORT: { // // Queries whether the driver is built for export. Used by the IPSEC components // to decide what key lengths to use for encryption. // IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IPSEC_QUERY_EXPORT")); dwSize = sizeof(IPSEC_QUERY_EXPORT); if (outputBufferLength < dwSize) { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IPSEC_QUERY_EXPORT: bad size: dwSize: %lx, input: %lx", dwSize, inputBufferLength)); status = STATUS_BUFFER_TOO_SMALL; break; } ((PIPSEC_QUERY_EXPORT)pvIoBuffer)->Export = FALSE; status = STATUS_SUCCESS; break; } case IOCTL_IPSEC_QUERY_SPI: { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("Entered Query SPI")); dwSize = sizeof(IPSEC_QUERY_SPI); if (inputBufferLength < dwSize) { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IPSEC_QUERY_SPI: bad size: dwSize: %lx, input: %lx", dwSize, inputBufferLength)); status = STATUS_BUFFER_TOO_SMALL; break; } status = IPSecQuerySpi((PIPSEC_QUERY_SPI)pvIoBuffer); break; } case IOCTL_IPSEC_DELETE_SA: { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("Entered Delete SA")); dwSize = sizeof(IPSEC_DELETE_SA); if (inputBufferLength < dwSize) { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IPSEC_DELETE_SA: bad size: dwSize: %lx, input: %lx", dwSize, inputBufferLength)); status = STATUS_BUFFER_TOO_SMALL; break; } status = IPSecDeleteSA((PIPSEC_DELETE_SA)pvIoBuffer); break; } case IOCTL_IPSEC_SET_OPERATION_MODE: { OPERATION_MODE LastMode = g_ipsec.OperationMode; IPSEC_DEBUG(LL_A, DBF_IOCTL, ("Entered Set Operation Mode")); dwSize = sizeof(IPSEC_SET_OPERATION_MODE); if (inputBufferLength < dwSize) { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IPSEC_SET_OPERATION_MODE: bad size: dwSize: %lx, input: %lx", dwSize, inputBufferLength)); status = STATUS_BUFFER_TOO_SMALL; break; } status = IPSecSetOperationMode((PIPSEC_SET_OPERATION_MODE)pvIoBuffer); if (IPSEC_BOOTTIME_STATEFUL_MODE == LastMode) { LARGE_INTEGER CurTime; LARGE_INTEGER Delta; NdisGetCurrentSystemTime(&CurTime); IPSecCleanupBoottimeStatefulStructs(); Delta = RtlLargeIntegerSubtract(CurTime,g_ipsec.StartTimeDelta); IPSEC_DEBUG(LL_A,DBF_BOOTTIME,("Delta %d %d",Delta.HighPart,Delta.LowPart)); } break; } case IOCTL_IPSEC_GET_OPERATION_MODE: { OPERATION_MODE CurrentMode = g_ipsec.OperationMode; dwSize = sizeof(IPSEC_GET_OPERATION_MODE); if (outputBufferLength< dwSize) { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IPSEC_SET_OPERATION_MODE: bad size: dwSize: %lx, input: %lx", dwSize, inputBufferLength)); status = STATUS_BUFFER_TOO_SMALL; break; } ((PIPSEC_SET_OPERATION_MODE)pvIoBuffer)->OperationMode = CurrentMode; break; } case IOCTL_IPSEC_SET_DIAGNOSTIC_MODE: { DWORD Mode; DWORD LogInterval; // Initialize the return status status = STATUS_SUCCESS; dwSize = sizeof (IPSEC_SET_DIAGNOSTIC_MODE); // Check Input Buffer Length if (inputBufferLength < dwSize) { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IPSEC_SET_DIAGNOSTIC_MODE : bad size: dwSize : %lx, input %lx", dwSize, inputBufferLength)); status = STATUS_BUFFER_TOO_SMALL; break; } // Get the input Parameters Mode = ((PIPSEC_SET_DIAGNOSTIC_MODE)pvIoBuffer)->Mode; LogInterval = ((PIPSEC_SET_DIAGNOSTIC_MODE)pvIoBuffer)->LogInterval; // Validate the diagnostic mode : Fail IOCTL if invalid if (Mode > IPSEC_DIAGNOSTIC_MAX ){ status = STATUS_INVALID_PARAMETER; break; } // Set the Diagnostic Mode g_ipsec.DiagnosticMode = Mode; // If LogInterval = 0 then dont change log interval if ( IPSEC_NOCHANGE_LOG_INTERVAL == LogInterval){ break; } // Default to MIN and MAX limits if (IPSEC_MIN_LOG_INTERVAL > LogInterval ){ LogInterval = IPSEC_MIN_LOG_INTERVAL; } if (IPSEC_MAX_LOG_INTERVAL < LogInterval ){ LogInterval = IPSEC_MAX_LOG_INTERVAL; } // Set the Log Interval g_ipsec.LogInterval = LogInterval; break; } case IOCTL_IPSEC_SET_TCPIP_STATUS: { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("Entered Set Tcpip Status")); if (Irp->RequestorMode != KernelMode) { status = STATUS_ACCESS_DENIED; break; } dwSize = sizeof(IPSEC_SET_TCPIP_STATUS); if (inputBufferLength < dwSize) { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IPSEC_SET_TCPIP_STATUS: bad size: dwSize: %lx, input: %lx", dwSize, inputBufferLength)); status = STATUS_BUFFER_TOO_SMALL; break; } status = IPSecSetTcpipStatus((PIPSEC_SET_TCPIP_STATUS)pvIoBuffer); break; } case IOCTL_IPSEC_REGISTER_PROTOCOL: { dwSize = sizeof(IPSEC_REGISTER_PROTOCOL); if (inputBufferLength < dwSize) { status = STATUS_BUFFER_TOO_SMALL; break; } status = IPSecRegisterProtocols( (PIPSEC_REGISTER_PROTOCOL) pvIoBuffer ); break; } default: { status = STATUS_INVALID_PARAMETER; break; } } IPSEC_DECREMENT(g_ipsec.NumIoctls); break ; } default: { IPSEC_DEBUG(LL_A, DBF_IOCTL, ("IPSEC: unknown IRP_MJ_XXX: %lx", irpStack->MajorFunction)); status = STATUS_INVALID_PARAMETER; break; } } ASSERT(status != STATUS_PENDING); ASSERT(KeGetCurrentIrql() <= APC_LEVEL); Irp->IoStatus.Status = status; Irp->IoStatus.Information = MIN(dwSize, outputBufferLength); IoCompleteRequest(Irp, IO_NO_INCREMENT); IPSEC_DEBUG(LL_A, DBF_IOCTL, ("Exiting IPSecDispath")); return status; } NTSTATUS IPSecBindToIP() /*++ Routine Description: This bind exchanges a number of entrypoints with IP so that - packets relevant to IPSEC can be handed over from the IP driver. - buffered packets can be flushed. - SA Table indices can be plumbed. - .... Arguments: NONE Return Value: The function value is the final status from the bind operation. --*/ { NTSTATUS status; IPSEC_FUNCTIONS ipsecFns; PAGED_CODE(); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Entering IPSecBindToIP")); ipsecFns.Version = IP_IPSEC_BIND_VERSION; ipsecFns.IPSecHandler = IPSecHandlePacket; ipsecFns.IPSecQStatus = IPSecQueryStatus; ipsecFns.IPSecSendCmplt = IPSecSendComplete; ipsecFns.IPSecNdisStatus = IPSecNdisStatus; ipsecFns.IPSecRcvFWPacket = IPSecRcvFWPacket; status = TCPIP_SET_IPSEC(&ipsecFns); if (status != IP_SUCCESS) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to bind to IP: %lx", status)); } else { IPSEC_DRIVER_BOUND() = TRUE; IPSEC_DRIVER_SEND_BOUND() = TRUE; } IPSEC_DEBUG(LL_A, DBF_LOAD, ("Exiting IPSecBindToIP")); return status; } NTSTATUS IPSecUnbindFromIP() /*++ Routine Description: This unbinds from the Filter Driver Arguments: NONE Return Value: The function value is the final status from the bind operation. --*/ { NTSTATUS status; IPSEC_FUNCTIONS ipsecFns={0}; PAGED_CODE(); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Entering IPSecUnbindFromIP")); ipsecFns.Version = IP_IPSEC_BIND_VERSION; status = TCPIP_UNSET_IPSEC(&ipsecFns); if (status != IP_SUCCESS) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to bind to IP: %lx", status)); } else { IPSEC_DRIVER_BOUND() = FALSE; } IPSEC_DEBUG(LL_A, DBF_LOAD, ("Exiting IPSecUnbindFromIP")); return status; } NTSTATUS IPSecUnbindSendFromIP() /*++ Routine Description: Unbinds just the send handler from IP Arguments: NONE Return Value: The function value is the final status from the bind operation. --*/ { NTSTATUS status; IPSEC_FUNCTIONS ipsecFns={0}; PAGED_CODE(); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Entering IPSecUnbindSendFromIP")); ipsecFns.Version = IP_IPSEC_BIND_VERSION; status = TCPIP_UNSET_IPSEC_SEND(&ipsecFns); if (status != IP_SUCCESS) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to bind to IP: %lx", status)); } else { IPSEC_DRIVER_SEND_BOUND() = FALSE; } IPSEC_DEBUG(LL_A, DBF_LOAD, ("Exiting IPSecUnbindSendFromIP")); return status; } NTSTATUS OpenRegKey( PHANDLE HandlePtr, PWCHAR KeyName ) /*++ Routine Description: Opens a Registry key and returns a handle to it. Arguments: HandlePtr - The varible into which to write the opened handle. KeyName - The name of the Registry key to open. Return Value: STATUS_SUCCESS or an appropriate failure code. --*/ { NTSTATUS Status; OBJECT_ATTRIBUTES ObjectAttributes; UNICODE_STRING UKeyName; PAGED_CODE(); RtlInitUnicodeString(&UKeyName, KeyName); memset(&ObjectAttributes, 0, sizeof(OBJECT_ATTRIBUTES)); InitializeObjectAttributes(&ObjectAttributes, &UKeyName, OBJ_CASE_INSENSITIVE, NULL, NULL); Status = ZwOpenKey(HandlePtr, KEY_READ, &ObjectAttributes); return Status; } NTSTATUS GetRegDWORDValue( HANDLE KeyHandle, PWCHAR ValueName, PULONG ValueData ) /*++ Routine Description: Reads a REG_DWORD value from the registry into the supplied variable. Arguments: KeyHandle - Open handle to the parent key of the value to read. ValueName - The name of the value to read. ValueData - The variable into which to read the data. Return Value: STATUS_SUCCESS or an appropriate failure code. --*/ { NTSTATUS status; ULONG resultLength; PKEY_VALUE_FULL_INFORMATION keyValueFullInformation; UCHAR keybuf[WORK_BUFFER_SIZE]; UNICODE_STRING UValueName; PAGED_CODE(); RtlInitUnicodeString(&UValueName, ValueName); keyValueFullInformation = (PKEY_VALUE_FULL_INFORMATION)keybuf; RtlZeroMemory(keyValueFullInformation, sizeof(keyValueFullInformation)); status = ZwQueryValueKey(KeyHandle, &UValueName, KeyValueFullInformation, keyValueFullInformation, WORK_BUFFER_SIZE, &resultLength); if (NT_SUCCESS(status)) { if (keyValueFullInformation->Type != REG_DWORD) { status = STATUS_INVALID_PARAMETER_MIX; } else { *ValueData = *((ULONG UNALIGNED *)((PCHAR)keyValueFullInformation + keyValueFullInformation->DataOffset)); } } return status; } NTSTATUS GetRegStringValue( HANDLE KeyHandle, PWCHAR ValueName, PKEY_VALUE_PARTIAL_INFORMATION *ValueData, PUSHORT ValueSize ) /*++ Routine Description: Reads a REG_*_SZ string value from the Registry into the supplied key value buffer. If the buffer string buffer is not large enough, it is reallocated. Arguments: KeyHandle - Open handle to the parent key of the value to read. ValueName - The name of the value to read. ValueData - Destination for the read data. ValueSize - Size of the ValueData buffer. Updated on output. Return Value: STATUS_SUCCESS or an appropriate failure code. --*/ { NTSTATUS status; ULONG resultLength; UNICODE_STRING UValueName; PAGED_CODE(); RtlInitUnicodeString(&UValueName, ValueName); status = ZwQueryValueKey( KeyHandle, &UValueName, KeyValuePartialInformation, *ValueData, (ULONG) *ValueSize, &resultLength ); if ( (status == STATUS_BUFFER_OVERFLOW) || (status == STATUS_BUFFER_TOO_SMALL) ) { PVOID temp; // // Free the old buffer and allocate a new one of the // appropriate size. // ASSERT(resultLength > (ULONG) *ValueSize); if (resultLength <= 0xFFFF) { temp = IPSecAllocateMemory(resultLength, IPSEC_TAG_IOCTL); if (temp != NULL) { if (*ValueData != NULL) { IPSecFreeMemory(*ValueData); } *ValueData = temp; *ValueSize = (USHORT) resultLength; status = ZwQueryValueKey(KeyHandle, &UValueName, KeyValuePartialInformation, *ValueData, *ValueSize, &resultLength ); ASSERT( (status != STATUS_BUFFER_OVERFLOW) && (status != STATUS_BUFFER_TOO_SMALL) ); } else { status = STATUS_INSUFFICIENT_RESOURCES; } } else { status = STATUS_BUFFER_TOO_SMALL; } } return status; } NTSTATUS GetRegBinaryValue( HANDLE KeyHandle, PWCHAR ValueName, PKEY_VALUE_PARTIAL_INFORMATION *ValueData, PUSHORT ValueSize ) /*++ Routine Description: Reads a binary from the Registry into the supplied key value buffer. If the buffer is not large enough, it is reallocated. Arguments: KeyHandle - Open handle to the parent key of the value to read. ValueName - The name of the value to read. ValueData - Destination for the read data. ValueSize - Size of the ValueData buffer. Updated on output. Return Value: STATUS_SUCCESS or an appropriate failure code. --*/ { NTSTATUS status; ULONG resultLength; UNICODE_STRING UValueName; PAGED_CODE(); RtlInitUnicodeString(&UValueName, ValueName); status = ZwQueryValueKey( KeyHandle, &UValueName, KeyValuePartialInformation, *ValueData, (ULONG) *ValueSize, &resultLength ); if ( (status == STATUS_BUFFER_OVERFLOW) || (status == STATUS_BUFFER_TOO_SMALL) ) { PVOID temp; // // Free the old buffer and allocate a new one of the // appropriate size. // ASSERT(resultLength > (ULONG) *ValueSize); if (resultLength <= 0xFFFF) { temp = IPSecAllocateMemory(resultLength, IPSEC_TAG_IOCTL); if (temp != NULL) { if (*ValueData != NULL) { IPSecFreeMemory(*ValueData); } *ValueData = temp; *ValueSize = (USHORT) resultLength; status = ZwQueryValueKey(KeyHandle, &UValueName, KeyValuePartialInformation, *ValueData, *ValueSize, &resultLength ); ASSERT( (status != STATUS_BUFFER_OVERFLOW) && (status != STATUS_BUFFER_TOO_SMALL) ); } else { status = STATUS_INSUFFICIENT_RESOURCES; } } else { status = STATUS_BUFFER_TOO_SMALL; } } return status; } NTSTATUS GetRegMultiSZValue( HANDLE KeyHandle, PWCHAR ValueName, PUNICODE_STRING ValueData ) /*++ Routine Description: Reads a REG_MULTI_SZ string value from the Registry into the supplied Unicode string. If the Unicode string buffer is not large enough, it is reallocated. Arguments: KeyHandle - Open handle to the parent key of the value to read. ValueName - The name of the value to read. ValueData - Destination Unicode string for the value data. Return Value: STATUS_SUCCESS or an appropriate failure code. --*/ { NTSTATUS status; ULONG resultLength; PKEY_VALUE_PARTIAL_INFORMATION keyValuePartialInformation; UNICODE_STRING UValueName; PAGED_CODE(); ValueData->Length = 0; status = GetRegStringValue( KeyHandle, ValueName, (PKEY_VALUE_PARTIAL_INFORMATION *) &(ValueData->Buffer), &(ValueData->MaximumLength) ); if (NT_SUCCESS(status)) { keyValuePartialInformation = (PKEY_VALUE_PARTIAL_INFORMATION) ValueData->Buffer; if (keyValuePartialInformation->Type == REG_MULTI_SZ) { ValueData->Length = (USHORT) keyValuePartialInformation->DataLength; RtlCopyMemory( ValueData->Buffer, &(keyValuePartialInformation->Data), ValueData->Length ); } else { status = STATUS_INVALID_PARAMETER_MIX; } } return status; } // GetRegMultiSZValue VOID IPSecReadRegistry() /*++ Routine Description: Reads config info from registry into g_ipsec Arguments: Return Value: status of the read. --*/ { NTSTATUS status; HANDLE hRegKey; WCHAR IPSecParametersRegistryKey[] = IPSEC_REG_KEY; BOOLEAN isAs = MmIsThisAnNtAsSystem(); g_ipsec.EnableOffload = IPSEC_DEFAULT_ENABLE_OFFLOAD; g_ipsec.DefaultSAIdleTime = IPSEC_DEFAULT_SA_IDLE_TIME; g_ipsec.LogInterval = IPSEC_DEFAULT_LOG_INTERVAL; g_ipsec.EventQueueSize = IPSEC_DEFAULT_EVENT_QUEUE_SIZE; g_ipsec.RekeyTime = IPSEC_DEFAULT_REKEY; g_ipsec.NoDefaultExempt = IPSEC_DEFAULT_NO_DEFAULT_EXEMPT; g_ipsec.OperationMode = IPSEC_BLOCK_MODE; g_ipsec.DiagnosticMode = IPSEC_DEFAULT_ENABLE_DIAGNOSTICS; if (isAs) { g_ipsec.CacheSize = IPSEC_DEFAULT_AS_CACHE_SIZE; g_ipsec.SAHashSize = IPSEC_DEFAULT_AS_SA_HASH_SIZE; } else { g_ipsec.CacheSize = IPSEC_DEFAULT_CACHE_SIZE; g_ipsec.SAHashSize = IPSEC_DEFAULT_SA_HASH_SIZE; } status = OpenRegKey(&hRegKey, IPSecParametersRegistryKey); if (NT_SUCCESS(status)) { // // Expected configuration values. We use reasonable defaults if they // aren't available for some reason. // IPSecRegReadDword( hRegKey, IPSEC_REG_PARAM_ENABLE_OFFLOAD, &g_ipsec.EnableOffload, IPSEC_DEFAULT_ENABLE_OFFLOAD, IPSEC_MAX_ENABLE_OFFLOAD, IPSEC_MIN_ENABLE_OFFLOAD); IPSecRegReadDword( hRegKey, IPSEC_REG_PARAM_SA_IDLE_TIME, &g_ipsec.DefaultSAIdleTime, IPSEC_DEFAULT_SA_IDLE_TIME, IPSEC_MAX_SA_IDLE_TIME, IPSEC_MIN_SA_IDLE_TIME); IPSecRegReadDword( hRegKey, IPSEC_REG_PARAM_EVENT_QUEUE_SIZE, &g_ipsec.EventQueueSize, IPSEC_DEFAULT_EVENT_QUEUE_SIZE, IPSEC_MAX_EVENT_QUEUE_SIZE, IPSEC_MIN_EVENT_QUEUE_SIZE); IPSecRegReadDword( hRegKey, IPSEC_REG_PARAM_LOG_INTERVAL, &g_ipsec.LogInterval, IPSEC_DEFAULT_LOG_INTERVAL, IPSEC_MAX_LOG_INTERVAL, IPSEC_MIN_LOG_INTERVAL); IPSecRegReadDword( hRegKey, IPSEC_REG_PARAM_REKEY_TIME, &g_ipsec.RekeyTime, IPSEC_DEFAULT_REKEY, IPSEC_MAX_REKEY, IPSEC_MIN_REKEY); IPSecRegReadDword( hRegKey, IPSEC_REG_PARAM_CACHE_SIZE, &g_ipsec.CacheSize, isAs? IPSEC_DEFAULT_AS_CACHE_SIZE: IPSEC_DEFAULT_CACHE_SIZE, IPSEC_MAX_CACHE_SIZE, IPSEC_MIN_CACHE_SIZE); IPSecRegReadDword( hRegKey, IPSEC_REG_PARAM_SA_HASH_SIZE, &g_ipsec.SAHashSize, isAs? IPSEC_DEFAULT_AS_SA_HASH_SIZE: IPSEC_DEFAULT_SA_HASH_SIZE, IPSEC_MAX_SA_HASH_SIZE, IPSEC_MIN_SA_HASH_SIZE); IPSecRegReadDword( hRegKey, IPSEC_REG_PARAM_NO_DEFAULT_EXEMPT, &g_ipsec.NoDefaultExempt, IPSEC_DEFAULT_NO_DEFAULT_EXEMPT, IPSEC_MAX_NO_DEFAULT_EXEMPT, IPSEC_MIN_NO_DEFAULT_EXEMPT); IPSecRegReadDword( hRegKey, IPSEC_REG_PARAM_ENABLE_DIAGNOSTICS, &g_ipsec.DiagnosticMode, IPSEC_DEFAULT_ENABLE_DIAGNOSTICS, IPSEC_MAX_ENABLE_DIAGNOSTICS, IPSEC_MIN_ENABLE_DIAGNOSTICS); IPSecRegReadDwordEx( hRegKey, IPSEC_REG_PARAM_OPERATION_MODE, &(ULONG)g_ipsec.OperationMode, IPSEC_OPERATION_MODE_MAX-1, // Max valid value 0, //Min valid value IPSEC_BYPASS_MODE,//Key not exist IPSEC_BLOCK_MODE, // Error in reading the key IPSEC_BLOCK_MODE);// Key value out of range IPSecRegReadDwordEx(hRegKey, IPSEC_REG_PARAM_DFLT_FWDING_BEHAVIOR, &(ULONG)g_ipsec.DefaultForwardingBehavior, IPSEC_FORWARD_MAX-1,//Max valid 0, IPSEC_FORWARD_BLOCK,//Key not exist IPSEC_FORWARD_BLOCK,// Error in reading IPSEC_FORWARD_BLOCK);//Value out of range ZwClose(hRegKey); } g_ipsec.CacheHalfSize = g_ipsec.CacheSize / 2; // // Init SAIdleTime for low memory reaper // IPSEC_CONVERT_SECS_TO_100NS(g_ipsec.SAIdleTime, g_ipsec.DefaultSAIdleTime); if (IS_DRIVER_BLOCK() || IS_DRIVER_BOOTSTATEFUL()) { // Make sure SPD will be starting ULONG SPDStart=0; WCHAR SPDParametersRegistryKey[] = SPD_REG_KEY; status = OpenRegKey(&hRegKey, SPDParametersRegistryKey); if (NT_SUCCESS(status)) { IPSecRegReadDword( hRegKey, SPD_REG_PARAM_START, &SPDStart, 0, 4, 0); if (SPDStart != 2) { g_ipsec.OperationMode = IPSEC_BYPASS_MODE; } ZwClose(hRegKey); } else { g_ipsec.OperationMode = IPSEC_BYPASS_MODE; } } IPSEC_DEBUG(LL_A,DBF_BOOTTIME,("IPSEC BOOT MODE %d\n",g_ipsec.OperationMode)); // // Log the boot mode to the system event log // IPSecLogBootOperationMode(); } NTSTATUS IPSecConvertRegExemptPolicy( PKEY_VALUE_PARTIAL_INFORMATION pKeyData, PIPSEC_EXEMPT_ENTRY *pBootExemptList, ULONG *pBootExemptListSize ) { ULONG i; LONG DataLeft = pKeyData->DataLength; PIPSEC_EXEMPT_ENTRY pCurEntry; ULONG TotalEntries=0; ULONG CurIndex=0; pCurEntry = (PIPSEC_EXEMPT_ENTRY)&(pKeyData->Data[0]); while (DataLeft >= (LONG)sizeof(IPSEC_EXEMPT_ENTRY)) { if ((pCurEntry->Type == EXEMPT_TYPE_PDP) && ((pCurEntry->Direction == EXEMPT_DIRECTION_INBOUND) || (pCurEntry->Direction == EXEMPT_DIRECTION_OUTBOUND)) && (pCurEntry->Size == sizeof(IPSEC_EXEMPT_ENTRY))) { TotalEntries++; } DataLeft -= pCurEntry->Size; if (pCurEntry->Size == 0) { break; } pCurEntry = (PIPSEC_EXEMPT_ENTRY) ((PBYTE)pCurEntry + pCurEntry->Size); } if (0 != TotalEntries ){ *pBootExemptList = (PIPSEC_EXEMPT_ENTRY)IPSecAllocateMemory(TotalEntries * sizeof(IPSEC_EXEMPT_ENTRY), IPSEC_TAG_INIT); } else { *pBootExemptList = NULL; *pBootExemptListSize=0; return STATUS_SUCCESS; } if (*pBootExemptList == NULL) { *pBootExemptListSize=0; return STATUS_INSUFFICIENT_RESOURCES; } pCurEntry = (PIPSEC_EXEMPT_ENTRY)&(pKeyData->Data[0]); DataLeft = pKeyData->DataLength; while (DataLeft >= (LONG)sizeof(IPSEC_EXEMPT_ENTRY)) { if ((pCurEntry->Type == EXEMPT_TYPE_PDP) && ((pCurEntry->Direction == EXEMPT_DIRECTION_INBOUND) || (pCurEntry->Direction == EXEMPT_DIRECTION_OUTBOUND)) && (pCurEntry->Size == sizeof(IPSEC_EXEMPT_ENTRY))){ RtlCopyMemory(&((*pBootExemptList)[CurIndex]),pCurEntry,sizeof(IPSEC_EXEMPT_ENTRY)); IPSEC_DEBUG(LL_A,DBF_BOOTTIME,("RegSrcPort %x : RegDstPort %x", (*pBootExemptList)[CurIndex].DestPort,(*pBootExemptList)[CurIndex].SrcPort)); (*pBootExemptList)[CurIndex].DestPort = NET_SHORT((*pBootExemptList)[CurIndex].DestPort); (*pBootExemptList)[CurIndex].SrcPort = NET_SHORT((*pBootExemptList)[CurIndex].SrcPort); IPSEC_DEBUG(LL_A,DBF_BOOTTIME,("Post swap RegSrcPort %x : RegDstPort %x", (*pBootExemptList)[CurIndex].DestPort,(*pBootExemptList)[CurIndex].SrcPort)); CurIndex++; } DataLeft -= pCurEntry->Size; if (pCurEntry->Size == 0) { break; } pCurEntry = (PIPSEC_EXEMPT_ENTRY) ((PBYTE)pCurEntry + pCurEntry->Size); } *pBootExemptListSize = TotalEntries; return STATUS_SUCCESS; } NTSTATUS IPSecReadExemptPolicy() { WCHAR IPSecParametersRegistryKey[] = IPSEC_REG_KEY; HANDLE hRegKey = NULL; USHORT BlobSize=0; NTSTATUS Status; PKEY_VALUE_PARTIAL_INFORMATION pKeyData=NULL; Status = OpenRegKey(&hRegKey, IPSecParametersRegistryKey); if (!NT_SUCCESS(Status)) { goto err; } Status = GetRegBinaryValue(hRegKey, IPSEC_REG_PARAM_EXEMPT_LIST, &pKeyData, &BlobSize); if (!NT_SUCCESS(Status)) { goto err; } if (pKeyData->Type != REG_BINARY) { Status = STATUS_INVALID_PARAMETER; goto err; } Status = IPSecConvertRegExemptPolicy(pKeyData, &g_ipsec.BootExemptList, &g_ipsec.BootExemptListSize); if (!NT_SUCCESS(Status)) { goto err; } err: if (hRegKey) { ZwClose(hRegKey); } if (pKeyData) { IPSecFreeMemory(pKeyData); } return Status; } NTSTATUS IPSecGeneralInit() /*++ Routine Description: General structures are initialized here. Arguments: None Return Value: --*/ { PSA_TABLE_ENTRY pSA; LONG i; NTSTATUS status = STATUS_SUCCESS; PAGED_CODE(); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Entering IPSecGeneralInit")); NdisGetCurrentSystemTime(&g_ipsec.StartTimeDelta); IPSEC_DEBUG(LL_A,DBF_LOAD, ("Entering IPSecGeneralInit\n")); // // Initialize our counters // g_ipsec.dwPacketsOnWrongSA = 0; // // init the acquireinfo struct // InitializeListHead(&g_ipsec.AcquireInfo.PendingAcquires); InitializeListHead(&g_ipsec.AcquireInfo.PendingNotifies); InitializeListHead(&g_ipsec.LarvalSAList); INIT_LOCK(&g_ipsec.LarvalListLock); INIT_LOCK(&g_ipsec.AcquireInfo.Lock); // // Set up the hashes/tables // InitializeMRSWLock(&g_ipsec.SADBLock); InitializeMRSWLock(&g_ipsec.SPIListLock); g_ipsec.IPProtInfo.pi_xmitdone = IPSecProtocolSendComplete; g_ipsec.IPProtInfo.pi_protocol = PROTOCOL_ESP; // // init filter linked lists // for (i = MIN_FILTER; i <= MAX_FILTER; i++) { InitializeListHead(&g_ipsec.FilterList[i]); } // // SAs in a hash table, hashed by // g_ipsec.pSADb = IPSecAllocateMemory(g_ipsec.SAHashSize * sizeof(SA_HASH), IPSEC_TAG_INIT); if (!g_ipsec.pSADb) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to alloc SADb hash")); return STATUS_INSUFFICIENT_RESOURCES; } IPSecInitFlag |= INIT_SA_DATABASE; IPSecZeroMemory(g_ipsec.pSADb, g_ipsec.SAHashSize * sizeof(SA_HASH)); for (i = 0; i < g_ipsec.SAHashSize; i++) { PSA_HASH Entry = &g_ipsec.pSADb[i]; InitializeListHead(&Entry->SAList); } // // Initialize the MDL pools. // status = IPSecInitMdlPool(); if (!NT_SUCCESS (status)) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to alloc MDL pools")); return STATUS_INSUFFICIENT_RESOURCES; } IPSecInitFlag |= INIT_MDL_POOLS; // // Initialize the cache structures. // if (!AllocateCacheStructures()) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to alloc cache structs")); return STATUS_INSUFFICIENT_RESOURCES; } IPSecInitFlag |= INIT_CACHE_STRUCT; // // Allocate EventQueue memory. // g_ipsec.IPSecLogMemory = IPSecAllocateMemory( g_ipsec.EventQueueSize * sizeof(IPSEC_EVENT_CTX), IPSEC_TAG_EVT_QUEUE); if (!g_ipsec.IPSecLogMemory) { return STATUS_INSUFFICIENT_RESOURCES; } IPSecInitFlag |= INIT_DEBUG_MEMORY; g_ipsec.IPSecLogMemoryLoc = &g_ipsec.IPSecLogMemory[0]; g_ipsec.IPSecLogMemoryEnd = &g_ipsec.IPSecLogMemory[g_ipsec.EventQueueSize * sizeof(IPSEC_EVENT_CTX)]; // // Init the timer stuff. // if (!IPSecInitTimer()) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to init timer")); return STATUS_INSUFFICIENT_RESOURCES; } IPSecInitFlag |= INIT_TIMERS; #if GPC status = IPSecGpcInitialize(); if (status != STATUS_SUCCESS) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to register GPC clients")); } #endif // // Arm the reaper timer // IPSEC_DEBUG(LL_A, DBF_LOAD, ("Starting ReaperTimer")); IPSecStartTimer(&g_ipsec.ReaperTimer, IPSecReaper, IPSEC_REAPER_TIME, (PVOID)NULL); // // Start EventLog timer // IPSEC_DEBUG(LL_A, DBF_LOAD, ("Starting EventLogTimer")); IPSecStartTimer(&g_ipsec.EventLogTimer, IPSecFlushEventLog, g_ipsec.LogInterval, (PVOID)NULL); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Exiting IPSecGeneralInit")); status = NsInitializeShim(IPSecDevice, &g_ipsec.ShimFunctions); if (status != STATUS_SUCCESS) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Failed to init natshim")); return status; } status = IPSecReadExemptPolicy(); if (!NT_SUCCESS (status)) { IPSEC_DEBUG(LL_A,DBF_LOAD, ("Failed to read exempt policy\n")); status = STATUS_SUCCESS; } // // Initialize the boot data structures // g_ipsec.BootBufferPool = NULL; g_ipsec.BootStatefulHT = NULL; if (IPSEC_BOOTTIME_STATEFUL_MODE == g_ipsec.OperationMode){ // // Allocate the boot time stateful exemption hash table // g_ipsec.BootStatefulHT = (PIPSEC_STATEFUL_HASH_TABLE)IPSecAllocateMemory(sizeof(IPSEC_STATEFUL_HASH_TABLE), IPSEC_TAG_STATEFUL_HT); if(g_ipsec.BootStatefulHT == NULL){ status = STATUS_INSUFFICIENT_RESOURCES; goto exit; } // // Allocate the memory pool for hash table entries // g_ipsec.BootBufferPool = (PIPSEC_HASH_BUFFER_POOL)IPSecAllocateMemory(sizeof(IPSEC_HASH_BUFFER_POOL),IPSEC_TAG_HASH_POOL); if(g_ipsec.BootBufferPool == NULL){ status = STATUS_INSUFFICIENT_RESOURCES; goto exit; } for (i=0;iEntry[i])); } RtlZeroMemory(g_ipsec.BootBufferPool,sizeof(IPSEC_HASH_BUFFER_POOL)); } return STATUS_SUCCESS; exit: return status; } NTSTATUS IPSecGeneralFree() /*++ Routine Description: Free general structures if IPSecGeneralInit fails. Arguments: None Return Value: --*/ { INT index; KIRQL kIrql; // // Free SA database. // if (IPSecInitFlag & INIT_SA_DATABASE) { if (g_ipsec.pSADb) { IPSecFreeMemory(g_ipsec.pSADb); } } // // Free MDL pool. // if (IPSecInitFlag & INIT_MDL_POOLS) { IPSecDeinitMdlPool(); } // // Free cache struct. // if (IPSecInitFlag & INIT_CACHE_STRUCT) { FreeExistingCache(); } // // Free EventQueue memory. // if (IPSecInitFlag & INIT_DEBUG_MEMORY) { if (g_ipsec.IPSecLogMemory) { IPSecFreeMemory(g_ipsec.IPSecLogMemory); } } // // Free timers allocated. // if (IPSecInitFlag & INIT_TIMERS) { for (index = 0; index < IPSEC_CLASS_MAX; index++) { IPSecFreeMemory(g_ipsec.TimerList[index].pTimers); } } AcquireWriteLock(&g_ipsec.SADBLock,&kIrql); if (g_ipsec.BootStatefulHT){ IPSecFreeMemory(g_ipsec.BootStatefulHT); g_ipsec.BootStatefulHT = NULL; } if (g_ipsec.BootBufferPool){ IPSecFreeMemory(g_ipsec.BootBufferPool); g_ipsec.BootBufferPool = NULL; } if (g_ipsec.BootExemptList){ IPSecFreeMemory(g_ipsec.BootExemptList); g_ipsec.BootExemptList = NULL; } ReleaseWriteLock(&g_ipsec.SADBLock, kIrql); return STATUS_SUCCESS; } NTSTATUS IPSecFreeConfig() /*++ Routine Description: Free the SA table etc. Arguments: None Return Value: --*/ { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Entering IPSecFreeConfig")); PAGED_CODE(); FreeExistingCache(); FreePatternDbase(); if (g_ipsec.IPSecLogMemory) { IPSecFreeMemory(g_ipsec.IPSecLogMemory); } IPSEC_DEBUG(LL_A, DBF_LOAD, ("Exiting IPSecFreeConfig")); return STATUS_SUCCESS; } NTSTATUS IPSecInitMdlPool() /*++ Routine Description: Create the MDL pool for AH and ESP headers. Arguments: None Return Value: --*/ { PAGED_CODE(); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Entering IPSecInitMdlPool")); g_ipsec.IPSecSmallBufferSize = IPSEC_SMALL_BUFFER_SIZE; g_ipsec.IPSecLargeBufferSize = IPSEC_LARGE_BUFFER_SIZE; g_ipsec.IPSecSendCompleteCtxSize = sizeof(IPSEC_SEND_COMPLETE_CONTEXT); g_ipsec.IPSecSmallBufferListDepth = IPSEC_LIST_DEPTH; g_ipsec.IPSecLargeBufferListDepth = IPSEC_LIST_DEPTH; g_ipsec.IPSecSendCompleteCtxDepth = IPSEC_LIST_DEPTH; g_ipsec.IPSecCacheLineSize = IPSEC_CACHE_LINE_SIZE; // // Initialize the lookaside lists. // g_ipsec.IPSecLookasideLists = IPSecAllocateMemory( sizeof(*g_ipsec.IPSecLookasideLists), IPSEC_TAG_LOOKASIDE_LISTS); if (g_ipsec.IPSecLookasideLists == NULL) { return STATUS_INSUFFICIENT_RESOURCES; } // // Initialize the IPSEC buffer lookaside lists. // ExInitializeNPagedLookasideList(&g_ipsec.IPSecLookasideLists->LargeBufferList, IPSecAllocateBufferPool, NULL, 0, g_ipsec.IPSecLargeBufferSize, IPSEC_TAG_BUFFER_POOL, (USHORT)g_ipsec.IPSecLargeBufferListDepth); ExInitializeNPagedLookasideList(&g_ipsec.IPSecLookasideLists->SmallBufferList, IPSecAllocateBufferPool, NULL, 0, g_ipsec.IPSecSmallBufferSize, IPSEC_TAG_BUFFER_POOL, (USHORT)g_ipsec.IPSecSmallBufferListDepth); ExInitializeNPagedLookasideList(&g_ipsec.IPSecLookasideLists->SendCompleteCtxList, NULL, NULL, 0, g_ipsec.IPSecSendCompleteCtxSize, IPSEC_TAG_SEND_COMPLETE, (USHORT)g_ipsec.IPSecSendCompleteCtxDepth); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Exiting IPSecInitMdlPool")); return STATUS_SUCCESS; } VOID IPSecDeinitMdlPool() /*++ Routine Description: Free the MDL pool for AH and ESP headers. Arguments: None Return Value: --*/ { PAGED_CODE(); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Entering IPSecDeinitMdlPool")); // // Destroy the lookaside lists. // if (g_ipsec.IPSecLookasideLists != NULL) { ExDeleteNPagedLookasideList(&g_ipsec.IPSecLookasideLists->LargeBufferList); ExDeleteNPagedLookasideList(&g_ipsec.IPSecLookasideLists->SmallBufferList); ExDeleteNPagedLookasideList(&g_ipsec.IPSecLookasideLists->SendCompleteCtxList); IPSecFreeMemory(g_ipsec.IPSecLookasideLists); } IPSEC_DEBUG(LL_A, DBF_LOAD, ("Exiting IPSecDeinitMdlPool")); } NTSTATUS IPSecQuiesce() /*++ Routine Description: Destroy MDL pools and run down all driver activity Arguments: None Return Value: --*/ { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Entering IPSecQuiesce")); IPSecDeinitMdlPool(); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Exiting IPSecQuiesce")); return STATUS_SUCCESS; } BOOLEAN AllocateCacheStructures() /*++ Routine Description: Allocates the necessary memory for cache (which is an array of pointers to cache entries) Allocates necessary number of cache entries (but doesnt initialize them) Allocates a small number of entries and puts them on the free list (doesnt initialize these either) Arguments: None Return Value: True if the function completely succeeds, else FALSE. If FALSE, it is upto the CALLER to do a rollback and clear any allocated memory --*/ { ULONG i; PAGED_CODE(); g_ipsec.ppCache = IPSecAllocateMemory(g_ipsec.CacheSize * sizeof(PFILTER_CACHE), IPSEC_TAG_INIT); if (!g_ipsec.ppCache) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("Couldnt allocate memory for Input Cache")); return FALSE; } IPSecZeroMemory(g_ipsec.ppCache, g_ipsec.CacheSize * sizeof(PFILTER_CACHE)); for (i = 0; i < g_ipsec.CacheSize; i++) { PFILTER_CACHE pTemp1; pTemp1 = IPSecAllocateMemory(sizeof(FILTER_CACHE), IPSEC_TAG_INIT); if (!pTemp1) { FreeExistingCache(); return FALSE; } IPSecZeroMemory(pTemp1, sizeof(FILTER_CACHE)); g_ipsec.ppCache[i] = pTemp1; } return TRUE; } VOID FreeExistingCache() /*++ Routine Description Frees all the cache entries, free entries and cache pointer array Arguments None Return Value None --*/ { ULONG i; PAGED_CODE(); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Freeing existing cache...")); IPSecResetCacheTable(); if (g_ipsec.ppCache) { for (i = 0; i < g_ipsec.CacheSize; i++) { if (g_ipsec.ppCache[i]) { ExFreePool(g_ipsec.ppCache[i]); } } ExFreePool(g_ipsec.ppCache); g_ipsec.ppCache = NULL; } } VOID FreePatternDbase() /*++ Routine Description Frees all filters and SAs. Arguments None Return Value None --*/ { PLIST_ENTRY pEntry; PFILTER pFilter; PSA_TABLE_ENTRY pSA; LONG i, j; PAGED_CODE(); // // Free all masked filters and associated (outbound) SAs // for (i = MIN_FILTER; i <= MAX_FILTER; i++) { while (!IsListEmpty(&g_ipsec.FilterList[i])) { pEntry = RemoveHeadList(&g_ipsec.FilterList[i]); pFilter = CONTAINING_RECORD(pEntry, FILTER, MaskedLinkage); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Freeing filter: %p", pFilter)); // // Free each SA under it. // for (j = 0; j < pFilter->SAChainSize; j++) { while (!IsListEmpty(&pFilter->SAChain[j])) { pEntry = RemoveHeadList(&pFilter->SAChain[j]); pSA = CONTAINING_RECORD(pEntry, SA_TABLE_ENTRY, sa_FilterLinkage); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Freeing SA: %p", pSA)); // // Remove SA from miniport if plumbed // if (pSA->sa_Flags & FLAGS_SA_HW_PLUMBED) { IPSecDelHWSA(pSA); } // // Also remove the inbound SAs from their SPI list // so we dont double free them below. // IPSecRemoveSPIEntry(pSA); // // Stop the timer if armed and deref SA. // IPSecStopTimerDerefSA(pSA); } } #if GPC IPSecUninstallGpcFilter(pFilter); #endif IPSecFreeFilter(pFilter); } } // // Free all SAs under the SPI hashes. // for (i = 0; i < g_ipsec.SAHashSize; i++) { PSA_HASH pHash = &g_ipsec.pSADb[i]; while (!IsListEmpty(&pHash->SAList)) { pEntry = RemoveHeadList(&pHash->SAList); pSA = CONTAINING_RECORD(pEntry, SA_TABLE_ENTRY, sa_SPILinkage); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Freeing SA: %p", pSA)); if (pSA->sa_Flags & FLAGS_SA_HW_PLUMBED) { IPSecDelHWSA(pSA); } IPSecStopTimerDerefSA(pSA); } } IPSecFreeMemory(g_ipsec.pSADb); IPSEC_DEBUG(LL_A, DBF_LOAD, ("Freed filters/SAs")); } SIZE_T IPSecCalculateBufferSize( IN SIZE_T BufferDataSize ) /*++ Routine Description: Determines the size of an AFD buffer structure given the amount of data that the buffer contains. Arguments: BufferDataSize - data length of the buffer. AddressSize - length of address structure for the buffer. Return Value: Number of bytes needed for an IPSEC_LA_BUFFER structure for data of this size. --*/ { SIZE_T mdlSize; SIZE_T bufferSize; ASSERT(BufferDataSize != 0); ASSERT(g_ipsec.IPSecCacheLineSize < 100); // // Determine the sizes of the various components of an IPSEC_LA_BUFFER // structure. Note that these are all worst-case calculations-- // actual sizes of the MDL and the buffer may be smaller. // bufferSize = BufferDataSize + g_ipsec.IPSecCacheLineSize; mdlSize = MmSizeOfMdl( (PVOID)(PAGE_SIZE-1), bufferSize ); return ((sizeof(IPSEC_LA_BUFFER) + mdlSize + bufferSize + 3) & ~3); } VOID IPSecInitializeBuffer( IN PIPSEC_LA_BUFFER IPSecBuffer, IN SIZE_T BufferDataSize ) /*++ Routine Description: Initializes an IPSec buffer. Sets up fields in the actual IPSEC_LA_BUFFER structure and initializes the MDL associated with the buffer. This routine assumes that the caller has properly allocated sufficient space for all this. Arguments: IPSecBuffer - points to the IPSEC_LA_BUFFER structure to initialize. BufferDataSize - the size of the data buffer that goes along with the buffer structure. Return Value: None --*/ { SIZE_T mdlSize; // // Set up the MDL pointer but don't build it yet. We have to wait // until after the data buffer is built to build the MDL. // mdlSize = MmSizeOfMdl( (PVOID)(PAGE_SIZE-1), BufferDataSize ); IPSecBuffer->Mdl = (PMDL)&IPSecBuffer->Data[0]; IPSEC_DEBUG(LL_A, DBF_POOL, ("IPSecBuffer: %p, MDL: %p", IPSecBuffer, IPSecBuffer->Mdl)); // // Set up the data buffer pointer and length. Note that the buffer // MUST begin on a cache line boundary so that we can use the fast // copy routines like RtlCopyMemory on the buffer. // IPSecBuffer->Buffer = (PVOID) (((ULONG_PTR)((PCHAR)IPSecBuffer->Mdl + mdlSize) + g_ipsec.IPSecCacheLineSize - 1 ) & ~((ULONG_PTR)(g_ipsec.IPSecCacheLineSize - 1))); IPSecBuffer->BufferLength = (ULONG)BufferDataSize; // Sundown - FIX // // Now build the MDL and set up a pointer to the MDL in the IRP. // MmInitializeMdl( IPSecBuffer->Mdl, IPSecBuffer->Buffer, BufferDataSize ); MmBuildMdlForNonPagedPool( IPSecBuffer->Mdl ); } PVOID IPSecAllocateBufferPool( IN POOL_TYPE PoolType, IN SIZE_T NumberOfBytes, IN ULONG Tag ) /*++ Routine Description: Used by the lookaside list allocation function to allocate a new IPSec buffer structure. The returned structure will be fully initialized. Arguments: PoolType - passed to ExAllocatePoolWithTag. NumberOfBytes - the number of bytes required for the data buffer portion of the IPSec buffer. Tag - passed to ExAllocatePoolWithTag. Return Value: PVOID - a fully initialized PIPSEC_LA_BUFFER, or NULL if the allocation attempt fails. --*/ { PIPSEC_LA_BUFFER IPSecBuffer; SIZE_T bytesRequired; // // The requested length must be the same as one of the standard // IPSec buffer sizes. // ASSERT( NumberOfBytes == g_ipsec.IPSecSmallBufferSize || NumberOfBytes == g_ipsec.IPSecLargeBufferSize ); // // Determine how much data we'll actually need for the buffer. // bytesRequired = IPSecCalculateBufferSize(NumberOfBytes); // // Get nonpaged pool for the buffer. // IPSecBuffer = IPSecAllocateMemory( bytesRequired, Tag ); if ( IPSecBuffer == NULL ) { return NULL; } // // Initialize the buffer and return a pointer to it. // IPSecInitializeBuffer( IPSecBuffer, NumberOfBytes ); return IPSecBuffer; } PIPSEC_LA_BUFFER IPSecGetBuffer( IN CLONG BufferDataSize, IN ULONG Tag ) /*++ Routine Description: Obtains a buffer of the appropriate size for the caller. Uses the preallocated buffers if possible, or else allocates a new buffer structure if required. Arguments: BufferDataSize - the size of the data buffer that goes along with the buffer structure. Return Value: PIPSEC_LA_BUFFER - a pointer to an IPSEC_LA_BUFFER structure, or NULL if one was not available or could not be allocated. --*/ { PIPSEC_LA_BUFFER IPSecBuffer; SIZE_T bufferSize; PLIST_ENTRY listEntry; PNPAGED_LOOKASIDE_LIST lookasideList; // // If possible, allocate the buffer from one of the lookaside lists. // if (BufferDataSize <= g_ipsec.IPSecLargeBufferSize) { if ( BufferDataSize <= g_ipsec.IPSecSmallBufferSize ) { lookasideList = &g_ipsec.IPSecLookasideLists->SmallBufferList; BufferDataSize = g_ipsec.IPSecSmallBufferSize; } else { lookasideList = &g_ipsec.IPSecLookasideLists->LargeBufferList; BufferDataSize = g_ipsec.IPSecLargeBufferSize; } IPSecBuffer = ExAllocateFromNPagedLookasideList( lookasideList ); if (!IPSecBuffer) { return NULL; } IPSecBuffer->Tag = Tag; return IPSecBuffer; } // // Couldn't find an appropriate buffer that was preallocated. // Allocate one manually. If the buffer size requested was // zero bytes, give them four bytes. This is because some of // the routines like MmSizeOfMdl() cannot handle getting passed // in a length of zero. // // !!! It would be good to ROUND_TO_PAGES for this allocation // if appropriate, then use entire buffer size. // if ( BufferDataSize == 0 ) { BufferDataSize = sizeof(ULONG); } bufferSize = IPSecCalculateBufferSize(BufferDataSize); IPSecBuffer = IPSecAllocateMemory(bufferSize, IPSEC_TAG_BUFFER_POOL); if ( IPSecBuffer == NULL ) { return NULL; } // // Initialize the IPSec buffer structure and return it. // IPSecInitializeBuffer(IPSecBuffer, BufferDataSize); IPSecBuffer->Tag = Tag; return IPSecBuffer; } VOID IPSecReturnBuffer ( IN PIPSEC_LA_BUFFER IPSecBuffer ) /*++ Routine Description: Returns an IPSec buffer to the appropriate global list, or frees it if necessary. Arguments: IPSecBufferHeader - points to the IPSec_BUFFER_HEADER structure to return or free. Return Value: None --*/ { PNPAGED_LOOKASIDE_LIST lookasideList; // // If appropriate, return the buffer to one of the IPSec buffer // lookaside lists. // if (IPSecBuffer->BufferLength <= g_ipsec.IPSecLargeBufferSize) { if (IPSecBuffer->BufferLength==g_ipsec.IPSecSmallBufferSize) { lookasideList = &g_ipsec.IPSecLookasideLists->SmallBufferList; } else { ASSERT (IPSecBuffer->BufferLength==g_ipsec.IPSecLargeBufferSize); lookasideList = &g_ipsec.IPSecLookasideLists->LargeBufferList; } ExFreeToNPagedLookasideList( lookasideList, IPSecBuffer ); return; } IPSecFreeMemory(IPSecBuffer); } NTSTATUS IPSecWriteEvent( PDRIVER_OBJECT IPSecDriverObject, IN ULONG EventCode, IN NTSTATUS NtStatusCode, IN ULONG OffloadStatus, IN ULONG ExtraStatus1, IN ULONG ExtraStatus2, IN PVOID RawDataBuffer, IN USHORT RawDataLength, IN USHORT NumberOfInsertionStrings, ... ) #define LAST_NAMED_ARGUMENT NumberOfInsertionStrings /*++ Routine Description: This function allocates an I/O error log record, fills it in and writes it to the I/O error log. Arguments: Return Value: None. --*/ { PIO_ERROR_LOG_PACKET ErrorLogEntry; va_list ParmPtr; // Pointer to stack parms. PCHAR DumpData; LONG Length; ULONG i, SizeOfRawData, RemainingSpace, TotalErrorLogEntryLength; ULONG SizeOfStringData = 0; PWSTR StringOffset, InsertionString; if (NumberOfInsertionStrings != 0) { va_start (ParmPtr, LAST_NAMED_ARGUMENT); for (i = 0; i < NumberOfInsertionStrings; i += 1) { InsertionString = va_arg (ParmPtr, PWSTR); Length = wcslen (InsertionString); while ((Length > 0) && (InsertionString[Length-1] == L' ')) { Length--; } SizeOfStringData += (Length + 1) * sizeof(WCHAR); } } // // Ideally we want the packet to hold the servername and ExtraInformation. // Usually the ExtraInformation gets truncated. // TotalErrorLogEntryLength = min (RawDataLength + sizeof(IO_ERROR_LOG_PACKET) + 1 + SizeOfStringData, ERROR_LOG_MAXIMUM_SIZE); RemainingSpace = TotalErrorLogEntryLength - FIELD_OFFSET(IO_ERROR_LOG_PACKET, DumpData); if (RemainingSpace > SizeOfStringData) { SizeOfRawData = RemainingSpace - SizeOfStringData; } else { SizeOfStringData = RemainingSpace; SizeOfRawData = 0; } ErrorLogEntry = IoAllocateErrorLogEntry (IPSecDriverObject, (UCHAR) TotalErrorLogEntryLength); if (ErrorLogEntry == NULL) { return(STATUS_INSUFFICIENT_RESOURCES); } // // Fill in the error log entry // ErrorLogEntry->ErrorCode = EventCode; ErrorLogEntry->UniqueErrorValue = OffloadStatus; ErrorLogEntry->FinalStatus = NtStatusCode; ErrorLogEntry->MajorFunctionCode = 0; ErrorLogEntry->RetryCount = 0; ErrorLogEntry->IoControlCode = 0; ErrorLogEntry->DeviceOffset.LowPart = ExtraStatus1; ErrorLogEntry->DeviceOffset.HighPart = ExtraStatus2; ErrorLogEntry->DumpDataSize = 0; ErrorLogEntry->NumberOfStrings = 0; ErrorLogEntry->SequenceNumber = 0; ErrorLogEntry->StringOffset = (USHORT) (ROUND_UP_COUNT (FIELD_OFFSET(IO_ERROR_LOG_PACKET, DumpData) + SizeOfRawData, ALIGN_WORD)); // // Append the dump data. This information is typically an SMB header. // if ((RawDataBuffer) && (SizeOfRawData)) { DumpData = (PCHAR) ErrorLogEntry->DumpData; Length = min (RawDataLength, (USHORT)SizeOfRawData); RtlCopyMemory (DumpData, RawDataBuffer, Length); ErrorLogEntry->DumpDataSize = (USHORT)Length; } // // Add the debug informatuion strings // if (NumberOfInsertionStrings) { StringOffset = (PWSTR) ((PCHAR)ErrorLogEntry + ErrorLogEntry->StringOffset); // // Set up ParmPtr to point to first of the caller's parameters. // va_start(ParmPtr, LAST_NAMED_ARGUMENT); for (i = 0 ; i < NumberOfInsertionStrings ; i+= 1) { InsertionString = va_arg(ParmPtr, PWSTR); Length = wcslen(InsertionString); while ( (Length > 0) && (InsertionString[Length-1] == L' ')) { Length--; } if (((Length + 1) * sizeof(WCHAR)) > SizeOfStringData) { Length = (SizeOfStringData/sizeof(WCHAR)) - 1; } if (Length > 0) { RtlCopyMemory (StringOffset, InsertionString, Length*sizeof(WCHAR)); StringOffset += Length; *StringOffset++ = L'\0'; SizeOfStringData -= (Length + 1) * sizeof(WCHAR); ErrorLogEntry->NumberOfStrings += 1; } } } IoWriteErrorLogEntry(ErrorLogEntry); return(STATUS_SUCCESS); } VOID IPSecLogEvents( IN PVOID Context ) /*++ Routine Description: Dumps events from the circular buffer to the eventlog when the circular buffer overflows. Arguments: Context - unused. Return Value: None --*/ { PIPSEC_LOG_EVENT pLogEvent; LONG LogSize; PUCHAR pLog; pLogEvent = (PIPSEC_LOG_EVENT)Context; LogSize = 0; pLog = (PUCHAR)pLogEvent + FIELD_OFFSET(IPSEC_LOG_EVENT, pLog[0]); while (LogSize < pLogEvent->LogSize) { PIPSEC_EVENT_CTX ctx = (PIPSEC_EVENT_CTX)pLog; if (ctx->EventCode == EVENT_IPSEC_DROP_PACKET_INBOUND || ctx->EventCode == EVENT_IPSEC_DROP_PACKET_OUTBOUND) { WCHAR IPAddrBufferS[(sizeof(IPAddr) * 4) + 1]; WCHAR IPAddrBufferD[(sizeof(IPAddr) * 4) + 1]; WCHAR IPProtocolBuffer[(sizeof(IPAddr) * 4) + 1]; WCHAR IPSPortBuffer[(sizeof(IPAddr) * 4) + 1]; WCHAR IPDPortBuffer[(sizeof(IPAddr) * 4) + 1]; PWCHAR stringlist[5]; IPHeader UNALIGNED *pIPH; USHORT SrcPort=0; USHORT DestPort=0; ULONG HeaderLen; pIPH = (IPHeader UNALIGNED *)ctx->pPacket; HeaderLen=(pIPH->iph_verlen & (UCHAR)~IP_VER_FLAG) << 2; IPSecIPAddrToUnicodeString( pIPH->iph_src, IPAddrBufferS); IPSecIPAddrToUnicodeString( pIPH->iph_dest, IPAddrBufferD); IPSecCountToUnicodeString ( pIPH->iph_protocol, IPProtocolBuffer); if (pIPH->iph_protocol == PROTOCOL_TCP || pIPH->iph_protocol == PROTOCOL_UDP) { RtlCopyMemory(&SrcPort,&ctx->pPacket[HeaderLen],sizeof(USHORT)); RtlCopyMemory(&DestPort,&ctx->pPacket[HeaderLen+sizeof(USHORT)],sizeof(USHORT)); } IPSecCountToUnicodeString ( NET_SHORT(SrcPort), IPSPortBuffer); IPSecCountToUnicodeString ( NET_SHORT(DestPort), IPDPortBuffer); IPSecWriteEvent( g_ipsec.IPSecDriverObject, ctx->EventCode, ctx->DropStatus.IPSecStatus, ctx->DropStatus.OffloadStatus, ctx->DropStatus.Flags, 0, ctx->pPacket, (USHORT)ctx->PacketSize, 5, IPAddrBufferS, IPAddrBufferD, IPProtocolBuffer, IPSPortBuffer, IPDPortBuffer); } else if (ctx->Addr && ctx->EventCount > 0) { WCHAR IPAddrBuffer[(sizeof(IPAddr) * 4) + 1]; WCHAR CountBuffer[MAX_COUNT_STRING_LEN + 1]; PWCHAR stringList[2]; IPSecIPAddrToUnicodeString( ctx->Addr, IPAddrBuffer); IPSecCountToUnicodeString( ctx->EventCount, CountBuffer); stringList[0] = CountBuffer; stringList[1] = IPAddrBuffer; LOG_EVENT( g_ipsec.IPSecDriverObject, ctx->EventCode, ctx->UniqueEventValue, 2, stringList, 0, NULL); } else if (ctx->Addr) { WCHAR IPAddrBuffer[(sizeof(IPAddr) * 4) + 1]; PWCHAR stringList[1]; IPSecIPAddrToUnicodeString( ctx->Addr, IPAddrBuffer); stringList[0] = IPAddrBuffer; LOG_EVENT( g_ipsec.IPSecDriverObject, ctx->EventCode, ctx->UniqueEventValue, 1, stringList, 0, NULL); } else { LOG_EVENT( g_ipsec.IPSecDriverObject, ctx->EventCode, ctx->UniqueEventValue, 0, NULL, 0, NULL); } if (ctx->pPacket) { IPSecFreeLogBuffer(ctx->pPacket); ctx->pPacket=NULL; } pLog += sizeof(IPSEC_EVENT_CTX); LogSize += sizeof(IPSEC_EVENT_CTX); } IPSecFreeMemory(pLogEvent); IPSEC_DECREMENT(g_ipsec.NumWorkers); } VOID IPSecBufferEvent( IN IPAddr Addr, IN ULONG EventCode, IN ULONG UniqueEventValue, IN BOOLEAN fBufferEvent ) /*++ Routine Description: Buffers events in a circular buffer; dumps them to the eventlog when the circular buffer overflows. Arguments: Addr - [OPTIONAL] the source IP addr of the offending peer. EventCode - Identifies the error message. UniqueEventValue - Identifies this instance of a given error message. Return Value: None --*/ { KIRQL kIrql; if (!(g_ipsec.DiagnosticMode & IPSEC_DIAGNOSTIC_ENABLE_LOG)) { return; } ACQUIRE_LOCK(&g_ipsec.EventLogLock, &kIrql); if (fBufferEvent) { PIPSEC_EVENT_CTX ctx; g_ipsec.IPSecBufferedEvents++; ctx = (PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc; ctx--; while (ctx >= (PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemory) { if (ctx->Addr == Addr && ctx->EventCode == EventCode && ctx->UniqueEventValue == UniqueEventValue) { // // Found a duplicate; update count and exit. // ctx->EventCount++; if (g_ipsec.IPSecBufferedEvents >= g_ipsec.EventQueueSize) { goto logit; } RELEASE_LOCK(&g_ipsec.EventLogLock, kIrql); return; } ctx--; } } ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->Addr = Addr; ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->EventCode = EventCode; ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->UniqueEventValue = UniqueEventValue; ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->pPacket=NULL; ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->PacketSize=0; if (fBufferEvent) { ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->EventCount = 1; } else { ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->EventCount = 0; } g_ipsec.IPSecLogMemoryLoc += sizeof(IPSEC_EVENT_CTX); logit: if (!fBufferEvent || g_ipsec.IPSecLogMemoryLoc >= g_ipsec.IPSecLogMemoryEnd || g_ipsec.IPSecBufferedEvents >= g_ipsec.EventQueueSize) { // // Flush the logs. // IPSecQueueLogEvent(); } RELEASE_LOCK(&g_ipsec.EventLogLock, kIrql); } NTSTATUS CopyOutboundPacketToBuffer( IN PUCHAR pIPHeader, IN PVOID pData, OUT PUCHAR * pPacket, OUT ULONG * PacketSize ) { PNDIS_BUFFER pTemp; ULONG Length; ULONG dataLength=0; IPHeader UNALIGNED *pIPH; ULONG HeaderLen=0; PUCHAR pBuffer; ULONG CopyPos=0; PUCHAR pPacketData; pIPH = (IPHeader UNALIGNED *)pIPHeader; pTemp = (PNDIS_BUFFER)pData; while (pTemp) { pBuffer = NULL; Length = 0; NdisQueryBufferSafe(pTemp, &pBuffer, &Length, NormalPagePriority); if (!pBuffer) { return STATUS_UNSUCCESSFUL; } dataLength += Length; pTemp = NDIS_BUFFER_LINKAGE(pTemp); } HeaderLen=(pIPH->iph_verlen & (UCHAR)~IP_VER_FLAG) << 2; dataLength += HeaderLen; if (dataLength > IPSEC_LOG_PACKET_SIZE) { dataLength = IPSEC_LOG_PACKET_SIZE; } if (dataLength < sizeof(IPHeader)) { // doesn't even have a full ip header return STATUS_UNSUCCESSFUL; } if ((pIPH->iph_protocol == PROTOCOL_TCP) || (pIPH->iph_protocol == PROTOCOL_UDP)) { if (dataLength - HeaderLen < 8) { // not enough room for ports return STATUS_UNSUCCESSFUL; } } *pPacket = IPSecAllocateLogBuffer(dataLength); if (! (*pPacket)) { return STATUS_UNSUCCESSFUL; } *PacketSize=dataLength; pTemp = (PNDIS_BUFFER)pData; CopyPos=0; while (pTemp && CopyPos < dataLength) { IPSecQueryNdisBuf(pTemp,&pPacketData,&Length); if (CopyPos + Length > dataLength) { Length = (dataLength - CopyPos); } RtlCopyMemory(*pPacket+CopyPos,pPacketData,Length); CopyPos += Length; pTemp = NDIS_BUFFER_LINKAGE(pTemp); } return STATUS_SUCCESS; } // // pData is data after IPHeader, IPRcvBuf. // NTSTATUS CopyInboundPacketToBuffer( IN PUCHAR pIPHeader, IN PVOID pData, OUT PUCHAR * pPacket, OUT ULONG * PacketSize ) { IPRcvBuf *pTemp; ULONG Length; ULONG dataLength=0; IPHeader UNALIGNED *pIPH; ULONG HeaderLen=0; PUCHAR pBuffer; ULONG CopyPos=0; PUCHAR pPacketData; pIPH = (IPHeader UNALIGNED *)pIPHeader; pTemp = (IPRcvBuf*)pData; while (pTemp) { pBuffer = NULL; Length = 0; IPSecQueryRcvBuf(pTemp, &pBuffer, &Length); if (!pBuffer) { return STATUS_UNSUCCESSFUL; } dataLength += Length; pTemp = IPSEC_BUFFER_LINKAGE(pTemp); } HeaderLen=(pIPH->iph_verlen & (UCHAR)~IP_VER_FLAG) << 2; dataLength += HeaderLen; if (dataLength > IPSEC_LOG_PACKET_SIZE) { dataLength = IPSEC_LOG_PACKET_SIZE; } // Sanity check length if (dataLength < sizeof(IPHeader)) { // doesn't even have a full ip header return STATUS_UNSUCCESSFUL; } if ((pIPH->iph_protocol == PROTOCOL_TCP) || (pIPH->iph_protocol == PROTOCOL_UDP)) { if (dataLength - HeaderLen < 8) { // not enough room for ports return STATUS_UNSUCCESSFUL; } } *pPacket = IPSecAllocateLogBuffer(dataLength); if (! (*pPacket)) { return STATUS_UNSUCCESSFUL; } *PacketSize=dataLength; pTemp = (IPRcvBuf*)pData; RtlCopyMemory(*pPacket,pIPH,HeaderLen); CopyPos=HeaderLen; while (pTemp && CopyPos < dataLength) { IPSecQueryRcvBuf(pTemp,&pPacketData,&Length); if (CopyPos + Length > dataLength) { Length = (dataLength - CopyPos); } RtlCopyMemory(*pPacket+CopyPos,pPacketData,Length); CopyPos += Length; pTemp = IPSEC_BUFFER_LINKAGE(pTemp); } return STATUS_SUCCESS; } VOID IPSecBufferPacketDrop( IN PUCHAR pIPHeader, IN PVOID pData, IN OUT PULONG pIpsecFlags, IN PIPSEC_DROP_STATUS pDropStatus ) /*++ Routine Description: Buffers events in a circular buffer; dumps them to the eventlog when the circular buffer overflows. Arguments: EventCode - Identifies the error message. Return Value: None --*/ { KIRQL kIrql; PIPSEC_EVENT_CTX ctx; IPHeader UNALIGNED *pIPH; PNDIS_BUFFER pTemp; PUCHAR pPacket=NULL; ULONG PacketSize=0; ULONG Status; BOOL bLockHeld=FALSE; pIPH = (IPHeader UNALIGNED *)pIPHeader; if (*pIpsecFlags & IPSEC_FLAG_INCOMING) { if (!(g_ipsec.DiagnosticMode & IPSEC_DIAGNOSTIC_INBOUND)) { // Don't log goto out; } Status=CopyInboundPacketToBuffer(pIPHeader, pData, &pPacket, &PacketSize); } else { if (!(g_ipsec.DiagnosticMode & IPSEC_DIAGNOSTIC_OUTBOUND)) { //Don't log goto out; } Status=CopyOutboundPacketToBuffer(pIPHeader, pData, &pPacket, &PacketSize); } if (Status != STATUS_SUCCESS) { goto out; } ACQUIRE_LOCK(&g_ipsec.EventLogLock, &kIrql); bLockHeld=TRUE; g_ipsec.IPSecBufferedEvents++; ctx = (PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc; ctx--; ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->Addr=pIPH->iph_src; if (*pIpsecFlags & IPSEC_FLAG_INCOMING) { ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->EventCode = EVENT_IPSEC_DROP_PACKET_INBOUND; } else { ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->EventCode = EVENT_IPSEC_DROP_PACKET_OUTBOUND; } ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->EventCount = 1; ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->pPacket = pPacket; ((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->PacketSize = PacketSize; if (pDropStatus) { RtlCopyMemory(&(((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->DropStatus), pDropStatus,sizeof(IPSEC_DROP_STATUS)); } else { RtlZeroMemory(&(((PIPSEC_EVENT_CTX)g_ipsec.IPSecLogMemoryLoc)->DropStatus), sizeof(IPSEC_DROP_STATUS)); } g_ipsec.IPSecLogMemoryLoc += sizeof(IPSEC_EVENT_CTX); if (g_ipsec.IPSecLogMemoryLoc >= g_ipsec.IPSecLogMemoryEnd || g_ipsec.IPSecBufferedEvents >= g_ipsec.EventQueueSize) { // // Flush the logs. // IPSecQueueLogEvent(); } out: if (bLockHeld) { RELEASE_LOCK(&g_ipsec.EventLogLock, kIrql); } } VOID IPSecQueueLogEvent( VOID ) /*++ Routine Description: Copies the LogMemory to a temporary buffer and schedule an event to flush logs. Arguments: None Return Value: None Notes: Called with EventLogLock held. --*/ { PIPSEC_LOG_EVENT pLogEvent; LONG LogSize; PUCHAR pLog; LogSize = (LONG)(g_ipsec.IPSecLogMemoryLoc - g_ipsec.IPSecLogMemory); // // Reset the log memory so we can record again. // g_ipsec.IPSecLogMemoryLoc = g_ipsec.IPSecLogMemory; g_ipsec.IPSecBufferedEvents = 0; if (LogSize <= 0) { ASSERT(FALSE); return; } pLogEvent = IPSecAllocateMemory(LogSize + FIELD_OFFSET(IPSEC_LOG_EVENT, pLog[0]), IPSEC_TAG_EVT_QUEUE); if (!pLogEvent) { return; } pLogEvent->LogSize = LogSize; pLog = (PUCHAR)pLogEvent + FIELD_OFFSET(IPSEC_LOG_EVENT, pLog[0]); RtlCopyMemory(pLog, g_ipsec.IPSecLogMemory, LogSize); // // Queue work item to dump these into the eventlog. // ExInitializeWorkItem(&pLogEvent->LogQueueItem, IPSecLogEvents, pLogEvent); ExQueueWorkItem(&pLogEvent->LogQueueItem, DelayedWorkQueue); IPSEC_INCREMENT(g_ipsec.NumWorkers); } #if FIPS BOOLEAN IPSecFipsInitialize( VOID ) /*++ Routine Description: Initialize the FIPS library table. Arguments: Called at PASSIVE level. Return Value: TRUE/FALSE. --*/ { UNICODE_STRING DeviceName; PDEVICE_OBJECT pFipsDeviceObject = NULL; PIRP pIrp; IO_STATUS_BLOCK StatusBlock; KEVENT Event; NTSTATUS status; PAGED_CODE(); // // Return success if FIPS already initialized. // if (IPSEC_DRIVER_INIT_FIPS()) { return TRUE; } RtlInitUnicodeString(&DeviceName, FIPS_DEVICE_NAME); // // Get the file and device objects for FIPS. // status = IoGetDeviceObjectPointer( &DeviceName, FILE_ALL_ACCESS, &g_ipsec.FipsFileObject, &pFipsDeviceObject); if (!NT_SUCCESS(status)) { g_ipsec.FipsFileObject = NULL; return FALSE; } // // Build the request to send to FIPS to get library table. // KeInitializeEvent(&Event, SynchronizationEvent, FALSE); pIrp = IoBuildDeviceIoControlRequest( IOCTL_FIPS_GET_FUNCTION_TABLE, pFipsDeviceObject, NULL, 0, &g_ipsec.FipsFunctionTable, sizeof(FIPS_FUNCTION_TABLE), FALSE, &Event, &StatusBlock); if (pIrp == NULL) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("IoBuildDeviceIoControlRequest IOCTL_FIPS_GET_FUNCTION_TABLE failed.")); ObDereferenceObject(g_ipsec.FipsFileObject); g_ipsec.FipsFileObject = NULL; return FALSE; } status = IoCallDriver(pFipsDeviceObject, pIrp); if (status == STATUS_PENDING) { status = KeWaitForSingleObject( &Event, Executive, KernelMode, FALSE, NULL); if (status == STATUS_SUCCESS) { status = StatusBlock.Status; } } if (status != STATUS_SUCCESS) { IPSEC_DEBUG(LL_A, DBF_LOAD, ("IoCallDriver: IOCTL_FIPS_GET_FUNCTION_TABLE failed %#x", status)); ObDereferenceObject(g_ipsec.FipsFileObject); g_ipsec.FipsFileObject = NULL; return FALSE; } IPSEC_DRIVER_INIT_FIPS() = TRUE; return TRUE; } #endif BOOLEAN IPSecCryptoInitialize( VOID ) /*++ Routine Description: Initialize RNG and FIPS library table. Arguments: None Return Value: TRUE/FALSE --*/ { PAGED_CODE(); if (IPSEC_DRIVER_INIT_CRYPTO()) { return TRUE; } #if FIPS // // Init the FIPS crypto library. // if (!IPSecFipsInitialize()) { return FALSE; } #endif // // Init the RC4 key for RNG. // if (!IPSEC_DRIVER_INIT_RNG()) { InitializeRNG(NULL); if (!IPSecInitRandom()) { ShutdownRNG(NULL); return FALSE; } IPSEC_DRIVER_INIT_RNG() = TRUE; } IPSEC_DRIVER_INIT_CRYPTO() = TRUE; return TRUE; } BOOLEAN IPSecCryptoDeinitialize( VOID ) /*++ Routine Description: Deinitialize RNG and dereference FipsFileObject. Arguments: None Return Value: TRUE/FALSE --*/ { PAGED_CODE(); // // Don't forget to shutdown RNG or we will leak memory. // if (IPSEC_DRIVER_INIT_RNG()) { ShutdownRNG(NULL); } #if FIPS // // Dereference FipsFileObject. // if (g_ipsec.FipsFileObject) { ObDereferenceObject(g_ipsec.FipsFileObject); } #endif return TRUE; } NTSTATUS IPSecRegisterProtocols( PIPSEC_REGISTER_PROTOCOL pIpsecRegisterProtocol ) { KIRQL kIrql = 0; if (pIpsecRegisterProtocol->RegisterProtocol == IPSEC_REGISTER_PROTOCOLS) { if (!IPSEC_GET_VALUE(gdwInitEsp)) { if (TCPIP_REGISTER_PROTOCOL( PROTOCOL_ESP, NULL, NULL, IPSecESPStatus, NULL, NULL, NULL )) { IPSEC_SET_VALUE(gdwInitEsp, 1); } else { ASSERT(FALSE); return (STATUS_INSUFFICIENT_RESOURCES); } } if (!IPSEC_GET_VALUE(gdwInitAh)) { if (TCPIP_REGISTER_PROTOCOL( PROTOCOL_AH, NULL, NULL, IPSecAHStatus, NULL, NULL, NULL )) { IPSEC_SET_VALUE(gdwInitAh, 1); } else { ASSERT(FALSE); TCPIP_DEREGISTER_PROTOCOL(PROTOCOL_ESP); IPSEC_SET_VALUE(gdwInitEsp, 0); return (STATUS_INSUFFICIENT_RESOURCES); } } } else if (pIpsecRegisterProtocol->RegisterProtocol == IPSEC_DEREGISTER_PROTOCOLS) { if (IPSEC_GET_VALUE(gdwInitEsp)) { TCPIP_DEREGISTER_PROTOCOL(PROTOCOL_ESP); IPSEC_SET_VALUE(gdwInitEsp, 0); } if (IPSEC_GET_VALUE(gdwInitAh)) { TCPIP_DEREGISTER_PROTOCOL(PROTOCOL_AH); IPSEC_SET_VALUE(gdwInitAh, 0); } AcquireWriteLock(&g_ipsec.SADBLock, &kIrql); ASSERT (gpParserIfEntry == NULL); FlushAllParserEntries(); ReleaseWriteLock(&g_ipsec.SADBLock, kIrql); } else { return (STATUS_INVALID_PARAMETER); } return (STATUS_SUCCESS); } VOID IPSecCleanupBoottimeStatefulStructs(VOID) { KIRQL kIrql; IPSEC_DEBUG(LL_A,DBF_BOOTTIME, ("Number of connections %d", g_ipsec.BootBufferPool->ulEntriesUsed)); AcquireWriteLock(&g_ipsec.SADBLock,&kIrql); //Release memory used for the boottime stateful //mode operation if (g_ipsec.BootStatefulHT){ IPSecFreeMemory(g_ipsec.BootStatefulHT); g_ipsec.BootStatefulHT = NULL; } if (g_ipsec.BootBufferPool){ IPSecFreeMemory(g_ipsec.BootBufferPool); g_ipsec.BootBufferPool = NULL; } //Let the exemptlist hang around //We will use it only if someone //moves us back into block mode. //We dont expect it to be too big //anyway. ReleaseWriteLock(&g_ipsec.SADBLock, kIrql); } VOID IPSecLogBootOperationMode(VOID) { NDIS_STATUS status; switch (g_ipsec.OperationMode){ case IPSEC_BOOTTIME_STATEFUL_MODE: status= LOG_EVENT( g_ipsec.IPSecDriverObject, EVENT_IPSEC_BOOT_STATEFUL_MODE, 1, 0, NULL, 0, NULL); break; case IPSEC_BYPASS_MODE: case IPSEC_SECURE_MODE: status = LOG_EVENT( g_ipsec.IPSecDriverObject, EVENT_IPSEC_BOOT_BYPASS_MODE, 1, 0, NULL, 0, NULL); break; case IPSEC_BLOCK_MODE: status = LOG_EVENT( g_ipsec.IPSecDriverObject, EVENT_IPSEC_BOOT_BLOCK_MODE, 1, 0, NULL, 0, NULL); break; default: break; } IPSEC_DEBUG(LL_A,DBF_BOOTTIME,("Boot Operation Mode = %d\n",g_ipsec.OperationMode)); } VOID IPSecLogChangeOperationMode(VOID) { switch (g_ipsec.OperationMode){ case IPSEC_BLOCK_MODE: LOG_EVENT( g_ipsec.IPSecDriverObject, EVENT_IPSEC_SET_BLOCK_MODE, 1, 0, NULL, 0, NULL); break; case IPSEC_SECURE_MODE: LOG_EVENT( g_ipsec.IPSecDriverObject, EVENT_IPSEC_SET_SECURE_MODE, 1, 0, NULL, 0, NULL); break; case IPSEC_BYPASS_MODE: LOG_EVENT( g_ipsec.IPSecDriverObject, EVENT_IPSEC_SET_BYPASS_MODE, 1, 0, NULL, 0, NULL); break; default: break; } }