windows-nt/Source/XPSP1/NT/base/cluster/clusnet/xport/cnpsend.c
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/*++
Copyright (c) 1997 Microsoft Corporation
Module Name:
cnpsend.c
Abstract:
Cluster Network Protocol send processing code.
Author:
Mike Massa (mikemas) January 24, 1997
Revision History:
Who When What
-------- -------- ----------------------------------------------
mikemas 01-24-97 created
Notes:
--*/
#include "precomp.h"
#pragma hdrstop
#include "cnpsend.tmh"
#ifdef ALLOC_PRAGMA
#pragma alloc_text(PAGE, CnpCreateSendRequestPool)
#endif // ALLOC_PRAGMA
//
// Private Utility Functions
//
PCN_RESOURCE
CnpCreateSendRequest(
IN PVOID Context
)
{
PCNP_SEND_REQUEST_POOL_CONTEXT context = Context;
PCNP_SEND_REQUEST request;
PCNP_HEADER cnpHeader;
ULONG cnpHeaderSize;
//
// The CNP header size includes signature data for version 2.
//
cnpHeaderSize = sizeof(CNP_HEADER);
if (context->CnpVersionNumber == 2) {
cnpHeaderSize += CNP_SIG_LENGTH(CX_SIGNATURE_LENGTH);
}
//
// Allocate a new send request. Include space for the upper protocol
// and CNP headers.
//
request = CnAllocatePool(
sizeof(CNP_SEND_REQUEST) + cnpHeaderSize +
((ULONG) context->UpperProtocolHeaderLength) +
context->UpperProtocolContextSize
);
if (request != NULL) {
//
// Allocate an MDL to describe the CNP and upper transport headers.
//
// On I64 Context has to be 64 bit aligned,
// let's put it before CnpHeader
if (context->UpperProtocolContextSize > 0) {
request->UpperProtocolContext = request + 1;
request->CnpHeader = ( ((PCHAR) request->UpperProtocolContext) +
context->UpperProtocolContextSize );
} else {
request->UpperProtocolContext = NULL;
request->CnpHeader = request + 1;
}
request->HeaderMdl = IoAllocateMdl(
request->CnpHeader,
(ULONG) (context->UpperProtocolHeaderLength +
cnpHeaderSize),
FALSE,
FALSE,
NULL
);
if (request->HeaderMdl != NULL) {
MmBuildMdlForNonPagedPool(request->HeaderMdl);
//
// Finish initializing the request.
//
request->UpperProtocolHeader = ( ((PCHAR) request->CnpHeader) +
cnpHeaderSize );
request->UpperProtocolHeaderLength =
context->UpperProtocolHeaderLength;
RtlZeroMemory(
&(request->TdiSendDatagramInfo),
sizeof(request->TdiSendDatagramInfo)
);
request->McastGroup = NULL;
//
// Fill in the constant CNP header values.
//
cnpHeader = request->CnpHeader;
cnpHeader->Version = context->CnpVersionNumber;
cnpHeader->NextHeader = context->UpperProtocolNumber;
return((PCN_RESOURCE) request);
}
CnFreePool(request);
}
return(NULL);
} // CnpCreateSendRequest
VOID
CnpDeleteSendRequest(
PCN_RESOURCE Resource
)
{
PCNP_SEND_REQUEST request = (PCNP_SEND_REQUEST) Resource;
IoFreeMdl(request->HeaderMdl);
CnFreePool(request);
return;
} // CnpDeleteSendRequest
//
// Routines Exported within the Cluster Transport
//
PCN_RESOURCE_POOL
CnpCreateSendRequestPool(
IN UCHAR CnpVersionNumber,
IN UCHAR UpperProtocolNumber,
IN USHORT UpperProtocolHeaderSize,
IN USHORT UpperProtocolContextSize,
IN USHORT PoolDepth
)
{
PCN_RESOURCE_POOL pool;
PCNP_SEND_REQUEST_POOL_CONTEXT context;
PAGED_CODE();
CnAssert((0xFFFF - sizeof(CNP_HEADER)) >= UpperProtocolHeaderSize);
pool = CnAllocatePool(
sizeof(CN_RESOURCE_POOL) +
sizeof(CNP_SEND_REQUEST_POOL_CONTEXT)
);
if (pool != NULL) {
context = (PCNP_SEND_REQUEST_POOL_CONTEXT) (pool + 1);
context->UpperProtocolNumber = UpperProtocolNumber;
context->UpperProtocolHeaderLength = UpperProtocolHeaderSize;
context->UpperProtocolContextSize = UpperProtocolContextSize;
context->CnpVersionNumber = CnpVersionNumber;
CnInitializeResourcePool(
pool,
PoolDepth,
CnpCreateSendRequest,
context,
CnpDeleteSendRequest
);
}
return(pool);
} // CnpCreateSendRequestPool
VOID
CnpCompleteSendPacketCommon(
IN PIRP Irp,
IN PCNP_SEND_REQUEST Request,
IN PMDL DataMdl
)
{
PCNP_NETWORK network = Request->Network;
ULONG bytesSent = (ULONG)Irp->IoStatus.Information;
NTSTATUS status = Irp->IoStatus.Status;
PCNP_HEADER cnpHeader = Request->CnpHeader;
CnVerifyCpuLockMask(
0, // Required
0xFFFFFFFF, // Forbidden
0 // Maximum
);
if (NT_SUCCESS(status)) {
//
// Subtract the CNP header from the count of bytes sent.
//
if (bytesSent >= sizeof(CNP_HEADER)) {
bytesSent -= sizeof(CNP_HEADER);
}
else {
CnAssert(FALSE);
bytesSent = 0;
}
//
// If CNP signed the message, subtract the signature
// data from the count of bytes sent.
//
if (cnpHeader->Version == CNP_VERSION_MULTICAST) {
CNP_SIGNATURE UNALIGNED * cnpSig;
cnpSig = (CNP_SIGNATURE UNALIGNED *)(cnpHeader + 1);
if (bytesSent >= (ULONG)CNP_SIGHDR_LENGTH &&
bytesSent >= cnpSig->PayloadOffset) {
bytesSent -= cnpSig->PayloadOffset;
} else {
CnAssert(FALSE);
bytesSent = 0;
}
}
CnTrace(CNP_SEND_DETAIL, CnpTraceSendComplete,
"[CNP] Send of packet to node %u on net %u complete, "
"bytes sent %u.",
cnpHeader->DestinationAddress, // LOGULONG
network->Id, // LOGULONG
bytesSent // LOGULONG
);
}
else {
//
// It is possible to reach this path with
// status = c0000240 (STATUS_REQUEST_ABORTED) and
// bytesSent > 0.
//
bytesSent = 0;
CnTrace(CNP_SEND_ERROR, CnpTraceSendFailedBelow,
"[CNP] Tcpip failed to send packet to node %u on net %u, "
"data len %u, status %!status!",
cnpHeader->DestinationAddress, // LOGULONG
network->Id, // LOGULONG
cnpHeader->PayloadLength, // LOGUSHORT
status // LOGSTATUS
);
}
//
// Remove the active reference we put on the network.
//
CnAcquireLock(&(network->Lock), &(network->Irql));
CnpActiveDereferenceNetwork(network);
//
// Free the TDI address buffer
//
CnFreePool(Request->TdiSendDatagramInfo.RemoteAddress);
//
// Call the upper protocol's completion routine
//
if (Request->CompletionRoutine) {
(*(Request->CompletionRoutine))(
status,
&bytesSent,
Request,
DataMdl
);
}
//
// Update the Information field of the completed IRP to
// reflect the actual bytes sent (adjusted for the CNP
// and upper protocol headers).
//
Irp->IoStatus.Information = bytesSent;
CnVerifyCpuLockMask(
0, // Required
0xFFFFFFFF, // Forbidden
0 // Maximum
);
return;
} // CnpCompleteSendPacketCommon
NTSTATUS
CnpCompleteSendPacketNewIrp(
IN PDEVICE_OBJECT DeviceObject,
IN PIRP Irp,
IN PVOID Context
)
{
PCNP_SEND_REQUEST request = Context;
PIRP upperIrp = request->UpperProtocolIrp;
PMDL dataMdl;
CnVerifyCpuLockMask(
0, // Required
0xFFFFFFFF, // Forbidden
0 // Maximum
);
//
// Unlink the data MDL chain from the header MDL.
//
CnAssert(Irp->MdlAddress == request->HeaderMdl);
dataMdl = request->HeaderMdl->Next;
request->HeaderMdl->Next = NULL;
Irp->MdlAddress = NULL;
CnpCompleteSendPacketCommon(Irp, request, dataMdl);
//
// Complete the upper-level IRP, if there is one
//
if (upperIrp != NULL) {
IF_CNDBG( CN_DEBUG_CNPSEND )
CNPRINT(("[CNP] CnpCompleteSendPacketNewIrp calling "
"CnCompleteRequest for IRP %p with status "
"%08x\n",
upperIrp, Irp->IoStatus.Status));
CnAcquireCancelSpinLock(&(upperIrp->CancelIrql));
CnCompletePendingRequest(
upperIrp,
Irp->IoStatus.Status, // status
(ULONG)Irp->IoStatus.Information // bytes returned
);
//
// The IoCancelSpinLock was released by the completion routine.
//
}
//
// Free the new IRP
//
IoFreeIrp(Irp);
CnVerifyCpuLockMask(
0, // Required
0xFFFFFFFF, // Forbidden
0 // Maximum
);
return(STATUS_MORE_PROCESSING_REQUIRED);
} // CnpCompleteSendPacketNewIrp
NTSTATUS
CnpCompleteSendPacketReuseIrp(
IN PDEVICE_OBJECT DeviceObject,
IN PIRP Irp,
IN PVOID Context
)
{
PCNP_SEND_REQUEST request = Context;
PMDL dataMdl;
CnVerifyCpuLockMask(
0, // Required
0xFFFFFFFF, // Forbidden
0 // Maximum
);
//
// Unlink the data MDL chain from the header MDL.
//
CnAssert(Irp->MdlAddress == request->HeaderMdl);
dataMdl = request->HeaderMdl->Next;
request->HeaderMdl->Next = NULL;
//
// Restore the requestor mode of the upper protocol IRP.
//
Irp->RequestorMode = request->UpperProtocolIrpMode;
//
// Restore the MDL of the upper protocol IRP.
//
Irp->MdlAddress = request->UpperProtocolMdl;
CnpCompleteSendPacketCommon(Irp, request, dataMdl);
if (Irp->PendingReturned) {
IoMarkIrpPending(Irp);
}
IF_CNDBG( CN_DEBUG_CNPSEND )
CNPRINT(("[CNP] CnpCompleteSendPacketReuseIrp returning "
"IRP %p to I/O Manager\n",
Irp));
CnVerifyCpuLockMask(
0, // Required
0xFFFFFFFF, // Forbidden
0 // Maximum
);
return(STATUS_SUCCESS);
} // CnpCompleteSendPacketReuseIrp
NTSTATUS
CnpSendPacket(
IN PCNP_SEND_REQUEST SendRequest,
IN CL_NODE_ID DestNodeId,
IN PMDL DataMdl,
IN USHORT DataLength,
IN BOOLEAN CheckDestState,
IN CL_NETWORK_ID NetworkId OPTIONAL
)
/*++
Routine Description:
Main send routine for CNP. Handles unicast and multicast
sends.
--*/
{
NTSTATUS status = STATUS_SUCCESS;
PCNP_HEADER cnpHeader = SendRequest->CnpHeader;
PIRP upperIrp = SendRequest->UpperProtocolIrp;
CN_IRQL tableIrql;
BOOLEAN multicast = FALSE;
CL_NETWORK_ID networkId = NetworkId;
CN_IRQL cancelIrql;
BOOLEAN cnComplete = FALSE;
BOOLEAN destNodeLocked = FALSE;
PCNP_NODE destNode;
ULONG sigDataLen;
PCNP_INTERFACE interface;
PCNP_NETWORK network;
BOOLEAN networkReferenced = FALSE;
PIRP irp;
PVOID addressBuffer = NULL;
PIO_COMPLETION_ROUTINE compRoutine;
PDEVICE_OBJECT targetDeviceObject;
PFILE_OBJECT targetFileObject;
BOOLEAN mcastGroupReferenced = FALSE;
CnVerifyCpuLockMask(
0, // Required
CNP_LOCK_RANGE, // Forbidden
CNP_PRECEEDING_LOCK_RANGE // Maximum
);
IF_CNDBG( CN_DEBUG_CNPSEND )
CNPRINT(("[CNP] CnpSendPacket called with upper IRP %p\n",
upperIrp));
//
// Make all the tests to see if we can send the packet.
//
//
// Acquire the node table lock to match the destination node id
// to a node object.
//
CnAcquireLock(&CnpNodeTableLock, &tableIrql);
if (CnpNodeTable == NULL) {
CnReleaseLock(&CnpNodeTableLock, tableIrql);
status = STATUS_NETWORK_UNREACHABLE;
goto error_exit;
}
//
// Fill in the local node ID while we still hold the node table lock.
//
CnAssert(CnLocalNodeId != ClusterInvalidNodeId);
cnpHeader->SourceAddress = CnLocalNodeId;
//
// Check first if the destination node id indicates that this is
// a multicast.
//
if (DestNodeId == ClusterAnyNodeId) {
//
// This is a multicast. For multicasts, we use the local
// node in place of the dest node to validate the network
// and interface.
//
multicast = TRUE;
destNode = CnpLockedFindNode(CnLocalNodeId, tableIrql);
}
//
// Not a multicast. The destination node id must be valid.
//
else if (!CnIsValidNodeId(DestNodeId)) {
CnReleaseLock(&CnpNodeTableLock, tableIrql);
status = STATUS_INVALID_ADDRESS_COMPONENT;
goto error_exit;
}
//
// Find the destination node object in the node table.
//
else {
destNode = CnpLockedFindNode(DestNodeId, tableIrql);
}
//
// The NodeTableLock was released. Verify that we know about
// the destination node.
//
if (destNode == NULL) {
status = STATUS_HOST_UNREACHABLE;
goto error_exit;
}
destNodeLocked = TRUE;
//
// CNP multicast messages must be signed.
//
if (multicast) {
CnAssert(((CNP_HEADER UNALIGNED *)(SendRequest->CnpHeader))
->Version = CNP_VERSION_MULTICAST);
//
// Sign the data, starting with the upper protocol header
// and finishing with the data payload.
//
// If we are requesting the current best multicast network,
// we need to make sure that the mcast group data structure
// is dereferenced.
//
mcastGroupReferenced = (BOOLEAN)(networkId == ClusterAnyNetworkId);
status = CnpSignMulticastMessage(
SendRequest,
DataMdl,
&networkId,
&sigDataLen
);
if (status != STATUS_SUCCESS) {
mcastGroupReferenced = FALSE;
goto error_exit;
}
} else {
sigDataLen = 0;
}
//
// Choose the destination interface.
//
if (networkId != ClusterAnyNetworkId) {
//
// we really want to send this packet over the indicated
// network. walk the node's interface list matching the
// supplied network id to the interface's network ID and
// send the packet on that interface
//
PLIST_ENTRY entry;
for (entry = destNode->InterfaceList.Flink;
entry != &(destNode->InterfaceList);
entry = entry->Flink
)
{
interface = CONTAINING_RECORD(
entry,
CNP_INTERFACE,
NodeLinkage
);
if ( interface->Network->Id == networkId ) {
break;
}
}
if ( entry == &destNode->InterfaceList ) {
//
// no network object with the specified ID. if
// this is the network the sender designated,
// fail the send.
//
status = STATUS_NETWORK_UNREACHABLE;
goto error_exit;
}
} else {
interface = destNode->CurrentInterface;
}
//
// Verify that we know about the destination interface.
//
if (interface == NULL) {
// No interface for node. Must be down. Note that the
// HOST_DOWN error code should cause the caller to give
// up immediately.
status = STATUS_HOST_DOWN;
// status = STATUS_HOST_UNREACHABLE;
goto error_exit;
}
//
// Verify that everything is online. If all looks okay,
// take an active reference on the network.
//
// For unicasts, verify the state of destination interface,
// node, and intervening network.
//
// For multicasts, verify the state of the network and
// its multicast capability.
//
network = interface->Network;
if ( (!multicast)
&&
( (interface->State > ClusnetInterfaceStateOfflinePending)
&&
(destNode->CommState == ClusnetNodeCommStateOnline)
)
)
{
//
// Everything checks out. Reference the network so
// it can't go offline while we are using it.
//
CnAcquireLockAtDpc(&(network->Lock));
CnAssert(network->State >= ClusnetNetworkStateOfflinePending);
CnpActiveReferenceNetwork(network);
CnReleaseLockFromDpc(&(network->Lock));
networkReferenced = TRUE;
} else {
//
// Either the node is not online or this is a
// multicast (in which case we don't bother checking
// the status of all the nodes). Figure out what to do.
//
if (!multicast && CheckDestState) {
//
// Caller doesn't want to send to a down node.
// Bail out. Note that the HOST_DOWN error code
// should cause the caller to give up immediately.
//
status = STATUS_HOST_DOWN;
// status = STATUS_HOST_UNREACHABLE;
goto error_exit;
}
CnAcquireLockAtDpc(&(network->Lock));
if (network->State <= ClusnetNetworkStateOfflinePending) {
//
// The chosen network is not online.
// Bail out.
//
CnReleaseLockFromDpc(&(network->Lock));
status = STATUS_HOST_UNREACHABLE;
goto error_exit;
}
//
// Multicast checks.
//
if (multicast) {
//
// Verify that the chosen network has been
// enabled for multicast.
//
if (!CnpIsNetworkMulticastCapable(network)) {
CnReleaseLockFromDpc(&(network->Lock));
status = STATUS_HOST_UNREACHABLE;
goto error_exit;
}
}
//
// The network is online, even if the host isn't.
// The caller doesn't care. Go for it.
//
CnpActiveReferenceNetwork(network);
CnReleaseLockFromDpc(&(network->Lock));
networkReferenced = TRUE;
}
//
// Allocate a buffer for the destination address.
//
addressBuffer = CnAllocatePool(interface->TdiAddressLength);
if (addressBuffer == NULL) {
status = STATUS_INSUFFICIENT_RESOURCES;
goto error_exit;
}
//
// Fill in the address buffer, and save it in the send
// request data structure.
//
if (multicast) {
PCNP_MULTICAST_GROUP mcastGroup = SendRequest->McastGroup;
CnAssert(mcastGroup != NULL);
CnAssert(
CnpIsIPv4McastTransportAddress(mcastGroup->McastTdiAddress)
);
CnAssert(
mcastGroup->McastTdiAddressLength == interface->TdiAddressLength
);
RtlMoveMemory(
addressBuffer,
mcastGroup->McastTdiAddress,
mcastGroup->McastTdiAddressLength
);
SendRequest->TdiSendDatagramInfo.RemoteAddressLength =
mcastGroup->McastTdiAddressLength;
if (mcastGroupReferenced) {
CnpDereferenceMulticastGroup(mcastGroup);
mcastGroupReferenced = FALSE;
SendRequest->McastGroup = NULL;
}
targetFileObject = network->DatagramFileObject;
targetDeviceObject = network->DatagramDeviceObject;
} else {
CnAssert(mcastGroupReferenced == FALSE);
RtlMoveMemory(
addressBuffer,
&(interface->TdiAddress),
interface->TdiAddressLength
);
SendRequest->TdiSendDatagramInfo.RemoteAddressLength =
interface->TdiAddressLength;
targetFileObject = network->DatagramFileObject;
targetDeviceObject = network->DatagramDeviceObject;
}
SendRequest->TdiSendDatagramInfo.RemoteAddress =
addressBuffer;
//
// Release the node lock.
//
CnReleaseLock(&(destNode->Lock), destNode->Irql);
destNodeLocked = FALSE;
//
// If there is an upper protocol IRP, see
// if it has enough stack locations.
//
if ( (upperIrp != NULL)
&&
(CnpIsIrpStackSufficient(upperIrp, targetDeviceObject))
) {
//
// We can use the upper protocol IRP.
//
irp = upperIrp;
compRoutine = CnpCompleteSendPacketReuseIrp;
//
// Ensure that IRP is marked as a kernel request,
// but first save the current requestor mode so
// that it can be restored later.
//
SendRequest->UpperProtocolIrpMode = irp->RequestorMode;
irp->RequestorMode = KernelMode;
//
// Save the upper protocol IRP MDL to restore
// later. This is probably the same as DataMdl,
// but we don't want to make any assumptions.
//
SendRequest->UpperProtocolMdl = irp->MdlAddress;
} else {
//
// We cannot use the upper protocol IRP.
//
// If there is an upper protocol IRP, it needs
// to be marked pending.
//
if (upperIrp != NULL) {
CnAcquireCancelSpinLock(&cancelIrql);
status = CnMarkRequestPending(
upperIrp,
IoGetCurrentIrpStackLocation(upperIrp),
NULL
);
CnReleaseCancelSpinLock(cancelIrql);
if (status == STATUS_CANCELLED) {
//
// Bail out
//
status = STATUS_INSUFFICIENT_RESOURCES;
goto error_exit;
} else {
//
// If IoAllocateIrp fails, we need
// to call CnCompletePendingRequest
// now that we've called
// CnMarkRequestPending.
//
cnComplete = TRUE;
}
}
//
// Allocate a new IRP
//
irp = IoAllocateIrp(
targetDeviceObject->StackSize,
FALSE
);
if (irp == NULL) {
status = STATUS_INSUFFICIENT_RESOURCES;
goto error_exit;
}
//
// Use the completion routine for having
// allocated a new IRP
//
compRoutine = CnpCompleteSendPacketNewIrp;
//
// Fill in IRP fields that are not specific
// to any one stack location.
//
irp->Flags = 0;
irp->RequestorMode = KernelMode;
irp->PendingReturned = FALSE;
irp->UserIosb = NULL;
irp->UserEvent = NULL;
irp->Overlay.AsynchronousParameters.UserApcRoutine = NULL;
irp->AssociatedIrp.SystemBuffer = NULL;
irp->UserBuffer = NULL;
irp->Tail.Overlay.Thread = PsGetCurrentThread();
irp->Tail.Overlay.AuxiliaryBuffer = NULL;
}
//
// Ok, we can finally send the packet.
//
SendRequest->Network = network;
//
// Link the data MDL chain after the header MDL.
//
SendRequest->HeaderMdl->Next = DataMdl;
//
// Finish building the CNP header.
//
cnpHeader->DestinationAddress = DestNodeId;
cnpHeader->PayloadLength =
SendRequest->UpperProtocolHeaderLength + DataLength;
//
// Build the next irp stack location.
//
TdiBuildSendDatagram(
irp,
targetDeviceObject,
targetFileObject,
compRoutine,
SendRequest,
SendRequest->HeaderMdl,
cnpHeader->PayloadLength + sizeof(CNP_HEADER) + sigDataLen,
&(SendRequest->TdiSendDatagramInfo)
);
CnTrace(CNP_SEND_DETAIL, CnpTraceSend,
"[CNP] Sending packet to node %u on net %u, "
"data len %u",
cnpHeader->DestinationAddress, // LOGULONG
network->Id, // LOGULONG
cnpHeader->PayloadLength // LOGUSHORT
);
//
// Now send the packet.
//
status = IoCallDriver(
targetDeviceObject,
irp
);
CnVerifyCpuLockMask(
0, // Required
CNP_LOCK_RANGE, // Forbidden
CNP_PRECEEDING_LOCK_RANGE // Maximum
);
return(status);
//
// The following code is only executed in an error condition,
// No send IRP has been submitted to a lower-level driver.
//
error_exit:
CnTrace(CNP_SEND_ERROR, CnpTraceSendFailedInternal,
"[CNP] Failed to send packet to node %u on net %u, "
"data len %u, status %!status!",
cnpHeader->DestinationAddress, // LOGULONG
NetworkId, // LOGULONG
cnpHeader->PayloadLength, // LOGUSHORT
status // LOGSTATUS
);
if (destNodeLocked) {
CnReleaseLock(&(destNode->Lock), destNode->Irql);
destNodeLocked = FALSE;
}
if (networkReferenced) {
//
// Remove the active reference we put on the network.
//
CnAcquireLock(&(network->Lock), &(network->Irql));
CnpActiveDereferenceNetwork(network);
networkReferenced = FALSE;
}
if (mcastGroupReferenced) {
CnAssert(SendRequest->McastGroup != NULL);
CnpDereferenceMulticastGroup(SendRequest->McastGroup);
SendRequest->McastGroup = NULL;
mcastGroupReferenced = FALSE;
}
if (addressBuffer != NULL) {
CnFreePool(addressBuffer);
}
//
// Call the upper protocol completion routine
//
if (SendRequest->CompletionRoutine) {
ULONG bytesSent = 0;
(*SendRequest->CompletionRoutine)(
status,
&bytesSent,
SendRequest,
DataMdl
);
}
//
// Complete the upper protocol IRP, if there is one
//
if (upperIrp) {
if (cnComplete) {
//
// CnMarkRequestPending was called for upperIrp.
//
IF_CNDBG( CN_DEBUG_CNPSEND )
CNPRINT(("[CNP] Calling CnCompletePendingRequest "
"for IRP %p with status %08x\n",
upperIrp, status));
CnCompletePendingRequest(upperIrp, status, 0);
} else {
IF_CNDBG( CN_DEBUG_CNPSEND )
CNPRINT(("[CNP] Completing IRP %p with status %08x\n",
upperIrp, status));
upperIrp->IoStatus.Status = status;
upperIrp->IoStatus.Information = 0;
IoCompleteRequest(upperIrp, IO_NO_INCREMENT);
}
}
CnVerifyCpuLockMask(
0, // Required
CNP_LOCK_RANGE, // Forbidden
CNP_PRECEEDING_LOCK_RANGE // Maximum
);
return(status);
} // CnpSendPacket