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windows-nt/Source/XPSP1/NT/base/fs/srv/xssupp.c
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/*++
Copyright (c) 1991 Microsoft Corporation
Module Name:
xssupp.c
Abstract:
This module contains the code necessary to support XACTSRV for down-level
remote APIs.
Author:
David Treadwell (davidtr) 05-Jan-1991
Revision History:
--*/
#include "precomp.h"
#include "xssupp.tmh"
#pragma hdrstop
//
// Xs forward declarations
//
VOID
SrvXsFreeSharedMemory (
VOID
);
#ifdef ALLOC_PRAGMA
#pragma alloc_text( PAGE, SrvXsConnect )
#pragma alloc_text( PAGE, SrvXsRequest )
#pragma alloc_text( PAGE, SrvXsLSOperation )
#pragma alloc_text( PAGE, SrvXsDisconnect )
#pragma alloc_text( PAGE, SrvXsFreeSharedMemory )
#pragma alloc_text( PAGE, SrvXsAllocateHeap )
#pragma alloc_text( PAGE, SrvXsFreeHeap )
#pragma alloc_text( PAGE, SrvXsPnpOperation )
#endif
//
// Xs internal Globals
//
//
// This count indicates how many outstanding transactions are using
// the XS shared memory. This prevents us from deleting the shared
// memory while it is still being accessed.
//
ULONG SrvXsSharedMemoryReference = 0;
NTSTATUS
SrvXsConnect (
IN PUNICODE_STRING PortName
)
/*++
Routine Description:
This routine performs all the work necessary to connect the server
to XACTSRV. It creates a section of shared memory to use, then
calls NtConnectPort to connect to the port that XACTSRV has already
created.
Arguments:
PortName - Name of the port XACTSRV has opened.
Return Value:
NTSTATUS - result of operation.
--*/
{
NTSTATUS status;
PORT_VIEW clientView;
SECURITY_QUALITY_OF_SERVICE dynamicQos;
PAGED_CODE( );
//
// Initialize variables so that we know what to close on exit.
//
SrvXsSectionHandle = NULL;
SrvXsPortHandle = NULL;
SrvXsPortMemoryHeap = NULL;
//
// Create the section to be used as unnamed shared memory for
// communication between the server and XACTSRV.
//
status = NtCreateSection(
&SrvXsSectionHandle,
SECTION_ALL_ACCESS,
NULL, // ObjectAttributes
&SrvXsSectionSize,
PAGE_READWRITE,
SEC_RESERVE,
NULL // FileHandle
);
if ( !NT_SUCCESS(status) ) {
IF_DEBUG(ERRORS) {
KdPrint(( "SrvXsConnect: NtCreateSection failed: %X\n", status ));
}
goto exit;
}
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsConnect: created section of %ld bytes, handle %p\n",
SrvXsSectionSize.LowPart, SrvXsSectionHandle ));
}
//
// Set up for a call to NtConnectPort and connect to XACTSRV. This
// includes a description of the port memory section so that the
// LPC connection logic can make the section visible to both the
// client and server processes.
//
clientView.Length = sizeof(clientView);
clientView.SectionHandle = SrvXsSectionHandle;
clientView.SectionOffset = 0;
clientView.ViewSize = SrvXsSectionSize.LowPart;
clientView.ViewBase = 0;
clientView.ViewRemoteBase = 0;
//
// Set up the security quality of service parameters to use over the
// port. Use dynamic tracking so that XACTSRV will impersonate the
// user that we are impersonating when we call NtRequestWaitReplyPort.
// If we used static tracking, XACTSRV would impersonate the context
// when the connection is made.
//
dynamicQos.ImpersonationLevel = SecurityImpersonation;
dynamicQos.ContextTrackingMode = SECURITY_DYNAMIC_TRACKING;
dynamicQos.EffectiveOnly = TRUE;
// !!! We might want to use a timeout value.
status = NtConnectPort(
&SrvXsPortHandle,
PortName,
&dynamicQos,
&clientView,
NULL, // ServerView
NULL, // MaxMessageLength
NULL, // ConnectionInformation
NULL // ConnectionInformationLength
);
if ( !NT_SUCCESS(status) ) {
IF_DEBUG(ERRORS) {
KdPrint(( "SrvXsConnect: NtConnectPort for port %wZ failed: %X\n",
PortName, status ));
}
goto exit;
}
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsConnect: conected to port %wZ, handle %p\n",
PortName, SrvXsPortHandle ));
}
//
// Store information about the section so that we can create pointers
// meaningful to XACTSRV.
//
SrvXsPortMemoryBase = clientView.ViewBase;
SrvXsPortMemoryDelta = PTR_DIFF_FULLPTR( clientView.ViewRemoteBase,
clientView.ViewBase );
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsConnect: port mem base %p, port mem delta %p\n",
SrvXsPortMemoryBase, (PVOID)SrvXsPortMemoryDelta ));
}
//
// Set up the port memory as heap.
//
// *** Note that we do our own heap serialization using
// SrvXsResource.
//
SrvXsPortMemoryHeap = RtlCreateHeap(
HEAP_NO_SERIALIZE, // Flags
SrvXsPortMemoryBase, // HeapBase
SrvXsSectionSize.LowPart, // ReserveSize
PAGE_SIZE, // CommitSize
NULL, // Lock
0 // Reserved
);
SrvXsActive = TRUE;
//
// Test it out to ensure everything is working right
//
SrvXsFreeHeap( SrvXsAllocateHeap( 100, &status ) );
return status;
exit:
if ( SrvXsSectionHandle != NULL ) {
SrvNtClose( SrvXsSectionHandle, FALSE );
}
if ( SrvXsPortHandle != NULL ) {
SrvNtClose( SrvXsPortHandle, FALSE );
}
return status;
} // SrvXsConnect
SMB_TRANS_STATUS
SrvXsRequest (
IN OUT PWORK_CONTEXT WorkContext
)
/*++
Routine Description:
This routine sends a remote API request to XACTSRV. It first
updates all the pointers in the transaction block so that they
are meaningful to XACTSRV, then sends a message over the port
indicating that there is a request in the shared memory ready to
be serviced. It then fixes all the pointers in the transaction
block.
Arguments:
WorkContext - a pointer to a work context block that has a pointer to
transaction block to use.
Return Value:
NTSTATUS - result of operation.
--*/
{
NTSTATUS status;
PCONNECTION connection = WorkContext->Connection;
PSESSION session = WorkContext->Session;
SMB_TRANS_STATUS returnStatus;
PTRANSACTION transaction;
XACTSRV_REQUEST_MESSAGE requestMessage;
XACTSRV_REPLY_MESSAGE replyMessage;
PWCH destPtr, sourcePtr, sourceEndPtr;
PAGED_CODE( );
//
// If this call is made on the NULL session, make sure it's one of
// the authorized apis.
//
transaction = WorkContext->Parameters.Transaction;
if ( session->IsNullSession && SrvRestrictNullSessionAccess ) {
USHORT apiNumber;
apiNumber = SmbGetUshort( (PSMB_USHORT)transaction->InParameters );
if ( apiNumber != API_WUserPasswordSet2 &&
apiNumber != API_WUserGetGroups &&
apiNumber != API_NetServerEnum2 &&
apiNumber != API_WNetServerReqChallenge &&
apiNumber != API_WNetServerAuthenticate &&
apiNumber != API_WNetServerPasswordSet &&
apiNumber != API_WNetAccountDeltas &&
apiNumber != API_WNetAccountSync &&
apiNumber != API_WWkstaUserLogoff &&
apiNumber != API_WNetWriteUpdateLog &&
apiNumber != API_WNetAccountUpdate &&
apiNumber != API_SamOEMChgPasswordUser2_P &&
apiNumber != API_NetServerEnum3 &&
apiNumber != API_WNetAccountConfirmUpdate ) {
IF_DEBUG(ERRORS) {
KdPrint(( "SrvXsRequest: Null session tried to call api.%d\n",
apiNumber ));
}
SrvSetSmbError( WorkContext, STATUS_ACCESS_DENIED );
return SmbTransStatusErrorWithoutData;
}
}
//
// Initialize the transport name pointer to make sure we can know if
// it has been allocated.
//
requestMessage.Message.DownLevelApi.TransportName = NULL;
//
// Convert the relevant pointers in the transaction block to the base
// in XACTSRV.
//
transaction->TransactionName.Buffer += SrvXsPortMemoryDelta;
transaction->InSetup += SrvXsPortMemoryDelta;
transaction->OutSetup += SrvXsPortMemoryDelta;
transaction->InParameters += SrvXsPortMemoryDelta;
transaction->OutParameters += SrvXsPortMemoryDelta;
transaction->InData += SrvXsPortMemoryDelta;
transaction->OutData += SrvXsPortMemoryDelta;
//
// Build the transport name in the message.
//
requestMessage.Message.DownLevelApi.TransportName =
SrvXsAllocateHeap(
WorkContext->Endpoint->TransportName.Length + sizeof(WCHAR),
&status
);
if ( requestMessage.Message.DownLevelApi.TransportName == NULL ) {
SrvSetSmbError( WorkContext, status );
returnStatus = SmbTransStatusErrorWithoutData;
goto exit;
}
requestMessage.Message.DownLevelApi.TransportNameLength =
WorkContext->Endpoint->TransportName.Length;
RtlCopyMemory(
requestMessage.Message.DownLevelApi.TransportName,
WorkContext->Endpoint->TransportName.Buffer,
WorkContext->Endpoint->TransportName.Length
);
//
// Null terminate the transport name.
//
requestMessage.Message.DownLevelApi.TransportName[ WorkContext->Endpoint->TransportName.Length / sizeof(WCHAR) ] = UNICODE_NULL;
//
// Adjust the transport name to be self relative within the buffer.
//
requestMessage.Message.DownLevelApi.TransportName =
(PWSTR)((PUCHAR)requestMessage.Message.DownLevelApi.TransportName +
SrvXsPortMemoryDelta);
//
// Build the server name in the message
//
RtlCopyMemory(
requestMessage.Message.DownLevelApi.ServerName,
WorkContext->Endpoint->TransportAddress.Buffer,
MIN( sizeof(requestMessage.Message.DownLevelApi.ServerName),
WorkContext->Endpoint->TransportAddress.Length )
);
requestMessage.Message.DownLevelApi.Transaction =
(PTRANSACTION)( (PCHAR)transaction + SrvXsPortMemoryDelta );
//
// Set up the message to send over the port.
//
requestMessage.PortMessage.u1.s1.DataLength =
(USHORT)( sizeof(requestMessage) - sizeof(PORT_MESSAGE) );
requestMessage.PortMessage.u1.s1.TotalLength = sizeof(requestMessage);
requestMessage.PortMessage.u2.ZeroInit = 0;
requestMessage.PortMessage.u2.s2.Type = LPC_KERNELMODE_MESSAGE;
requestMessage.MessageType = XACTSRV_MESSAGE_DOWN_LEVEL_API;
//
// Copy the client machine name for XACTSRV, skipping over the
// initial "\\", and deleting trailing spaces.
//
destPtr = requestMessage.Message.DownLevelApi.ClientMachineName;
sourcePtr =
connection->PagedConnection->ClientMachineNameString.Buffer + 2;
sourceEndPtr = sourcePtr
+ min( connection->PagedConnection->ClientMachineNameString.Length,
sizeof(requestMessage.Message.DownLevelApi.ClientMachineName) /
sizeof(WCHAR) - 1 );
while ( sourcePtr < sourceEndPtr && *sourcePtr != UNICODE_NULL ) {
*destPtr++ = *sourcePtr++;
}
*destPtr-- = UNICODE_NULL;
while ( destPtr >= requestMessage.Message.DownLevelApi.ClientMachineName
&&
*destPtr == L' ' ) {
*destPtr-- = UNICODE_NULL;
}
//
// Copy the lanman session key. This will be used to decrypt doubly
// encrypted passwords.
//
RtlCopyMemory(
requestMessage.Message.DownLevelApi.LanmanSessionKey,
session->LanManSessionKey,
MSV1_0_LANMAN_SESSION_KEY_LENGTH
);
//
// Set the flags
//
requestMessage.Message.DownLevelApi.Flags = 0;
if ( IS_NT_DIALECT( connection->SmbDialect ) ) {
requestMessage.Message.DownLevelApi.Flags |= XS_FLAGS_NT_CLIENT;
}
//
// Send the message to XACTSRV and wait for a response message.
//
// !!! We may want to put a timeout on this.
//
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsRequest: Sending message at %p, port mem %p.\n",
&requestMessage, transaction ));
}
status = IMPERSONATE( WorkContext );
if( NT_SUCCESS( status ) ) {
status = NtRequestWaitReplyPort(
SrvXsPortHandle,
(PPORT_MESSAGE)&requestMessage,
(PPORT_MESSAGE)&replyMessage
);
REVERT( );
}
if ( !NT_SUCCESS(status) ) {
IF_DEBUG(ERRORS) {
KdPrint(( "SrvXsRequest: NtRequestWaitReplyPort failed: %X\n",
status ));
}
SrvSetSmbError( WorkContext, status );
returnStatus = SmbTransStatusErrorWithoutData;
goto exit;
}
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsRequest: Received response at %p\n", &replyMessage ));
}
//
// Check the status returned in the reply.
//
status = replyMessage.Message.DownLevelApi.Status;
if ( !NT_SUCCESS(status) ) {
IF_DEBUG(SMB_ERRORS) {
KdPrint(( "SrvXsRequest: XACTSRV reply had status %X\n", status ));
}
SrvSetSmbError( WorkContext, status );
returnStatus = SmbTransStatusErrorWithoutData;
goto exit;
}
returnStatus = SmbTransStatusSuccess;
exit:
//
// We're done with the API. Free up the buffer containing the
// transport name.
//
if ( requestMessage.Message.DownLevelApi.TransportName != NULL ) {
requestMessage.Message.DownLevelApi.TransportName =
(PWSTR)((PUCHAR)requestMessage.Message.DownLevelApi.TransportName -
SrvXsPortMemoryDelta);
SrvXsFreeHeap( requestMessage.Message.DownLevelApi.TransportName );
}
//
// Convert the relevant pointers in the transaction block back to
// the server base.
//
transaction->TransactionName.Buffer -= SrvXsPortMemoryDelta;
transaction->InSetup -= SrvXsPortMemoryDelta;
transaction->OutSetup -= SrvXsPortMemoryDelta;
transaction->InParameters -= SrvXsPortMemoryDelta;
transaction->OutParameters -= SrvXsPortMemoryDelta;
transaction->InData -= SrvXsPortMemoryDelta;
transaction->OutData -= SrvXsPortMemoryDelta;
return returnStatus;
} // SrvXsRequest
NTSTATUS
SrvXsLSOperation (
IN PSESSION Session,
IN ULONG Type
)
/*++
Routine Description:
This routine causes the Xact service to do an NtLSRequest call
Arguments:
Session - a pointer to the session structure involved in the request
Type - either XACTSRV_MESSAGE_LSREQUEST or XACTSRV_MESSAGE_LSRELEASE
depending on whether a license is being requested or being
released.
Return Value:
STATUS_SUCCESS if the license was granted
Notes:
Once a license is granted for a particular session, it is never released
until the session is deallocated. Therefore, it is only necessary to
hold the Session->Connection->LicenseLock when we are checking for
acquisition of the license.
We don't need licenses if we are running on a workstation.
We don't try for licenses over NULL sessions
--*/
{
XACTSRV_REQUEST_MESSAGE requestMessage;
XACTSRV_REPLY_MESSAGE replyMessage;
NTSTATUS status;
ULONG requestLength;
UNICODE_STRING userName, userDomain;
PAGED_CODE( );
if( SrvProductTypeServer == FALSE || !SrvXsActive ) {
return STATUS_SUCCESS;
}
switch( Type ) {
case XACTSRV_MESSAGE_LSREQUEST:
if( Session->IsNullSession ||
Session->IsLSNotified ) {
return STATUS_SUCCESS;
}
ACQUIRE_LOCK( &Session->Connection->LicenseLock );
if( Session->IsLSNotified == TRUE ) {
RELEASE_LOCK( &Session->Connection->LicenseLock );
return STATUS_SUCCESS;
}
//
// Put domainname\username in the message
//
status = SrvGetUserAndDomainName( Session, &userName, &userDomain );
if( !NT_SUCCESS( status ) ) {
RELEASE_LOCK( &Session->Connection->LicenseLock );
return status;
}
requestMessage.Message.LSRequest.UserName =
SrvXsAllocateHeap( userDomain.Length + sizeof(WCHAR)
+ userName.Length + sizeof(WCHAR), &status
);
if ( requestMessage.Message.LSRequest.UserName == NULL ) {
RELEASE_LOCK( &Session->Connection->LicenseLock );
SrvReleaseUserAndDomainName( Session, &userName, &userDomain );
return status;
}
if( userDomain.Length ) {
RtlCopyMemory(
requestMessage.Message.LSRequest.UserName,
userDomain.Buffer,
userDomain.Length
);
}
requestMessage.Message.LSRequest.UserName[ userDomain.Length / sizeof(WCHAR) ] = L'\\';
RtlCopyMemory(
requestMessage.Message.LSRequest.UserName + (userDomain.Length / sizeof( WCHAR )) + 1,
userName.Buffer,
userName.Length
);
requestMessage.Message.LSRequest.UserName[ (userDomain.Length
+ userName.Length) / sizeof( WCHAR )
+ 1 ]
= UNICODE_NULL;
requestMessage.Message.LSRequest.IsAdmin = SrvIsAdmin( Session->UserHandle );
IF_DEBUG(LICENSE) {
KdPrint(("XACTSRV_MESSAGE_LSREQUEST: %ws, IsAdmin: %d\n",
requestMessage.Message.LSRequest.UserName,
requestMessage.Message.LSRequest.IsAdmin ));
}
// Adjust the buffer pointers to be self relative within the buffer.
requestMessage.Message.LSRequest.UserName =
(PWSTR)((PUCHAR)requestMessage.Message.LSRequest.UserName + SrvXsPortMemoryDelta);
SrvReleaseUserAndDomainName( Session, &userName, &userDomain );
break;
case XACTSRV_MESSAGE_LSRELEASE:
if( Session->IsLSNotified == FALSE )
return STATUS_SUCCESS;
IF_DEBUG(LICENSE) {
KdPrint(("XACTSRV_MESSAGE_LSRELEASE: Handle %p\n", Session->hLicense ));
}
requestMessage.Message.LSRelease.hLicense = Session->hLicense;
break;
default:
ASSERT( !"Bad Type" );
return STATUS_INVALID_PARAMETER;
}
requestMessage.PortMessage.u1.s1.DataLength =
(USHORT)( sizeof(requestMessage) - sizeof(PORT_MESSAGE) );
requestMessage.PortMessage.u1.s1.TotalLength = sizeof(requestMessage);
requestMessage.PortMessage.u2.ZeroInit = 0;
requestMessage.PortMessage.u2.s2.Type = LPC_KERNELMODE_MESSAGE;
requestMessage.MessageType = Type;
//
// Send the message to XACTSRV and wait for a response message.
//
// !!! We may want to put a timeout on this.
//
status = NtRequestWaitReplyPort(
SrvXsPortHandle,
(PPORT_MESSAGE)&requestMessage,
(PPORT_MESSAGE)&replyMessage
);
IF_DEBUG( ERRORS ) {
if( !NT_SUCCESS( status ) ) {
KdPrint(( "SrvXsLSOperation: NtRequestWaitReplyPort failed: %X\n", status ));
}
}
if( NT_SUCCESS( status ) )
status = replyMessage.Message.LSRequest.Status;
switch( Type ) {
case XACTSRV_MESSAGE_LSREQUEST:
requestMessage.Message.LSRequest.UserName =
(PWSTR)((PUCHAR)requestMessage.Message.LSRequest.UserName - SrvXsPortMemoryDelta);
SrvXsFreeHeap( requestMessage.Message.LSRequest.UserName );
if( NT_SUCCESS( status ) ) {
Session->IsLSNotified = TRUE;
Session->hLicense = replyMessage.Message.LSRequest.hLicense;
IF_DEBUG( LICENSE ) {
KdPrint((" hLicense = %p\n", Session->hLicense ));
}
}
RELEASE_LOCK( &Session->Connection->LicenseLock );
break;
case XACTSRV_MESSAGE_LSRELEASE:
Session->IsLSNotified = FALSE;
break;
}
IF_DEBUG( LICENSE ) {
if( !NT_SUCCESS( status ) ) {
KdPrint(( " SrvXsLSOperation returning status %X\n", status ));
}
}
return status;
} // SrvXsLSOperation
VOID
SrvXsPnpOperation(
PUNICODE_STRING DeviceName,
BOOLEAN Bind
)
/*++
Routine Description:
This routine sends the Xact service a PNP notification
--*/
{
PXACTSRV_REQUEST_MESSAGE requestMessage;
PXACTSRV_REQUEST_MESSAGE responseMessage;
ULONG len;
NTSTATUS status;
PAGED_CODE( );
if( SrvXsPortHandle == NULL ) {
IF_DEBUG( PNP ) {
KdPrint(( "SRV: SrvXsPnpOperation no SRVSVC handle!\n" ));
}
return;
}
len = (sizeof( XACTSRV_REQUEST_MESSAGE ) * 2) + DeviceName->Length + sizeof( WCHAR );
requestMessage = SrvXsAllocateHeap( len, &status );
if( requestMessage == NULL ) {
IF_DEBUG( PNP ) {
KdPrint(( "SRV: SrvXsPnpOperation unable to allocate memory: %X\n", status ));
}
return;
}
RtlZeroMemory( requestMessage, len );
responseMessage = requestMessage + 1;
requestMessage->Message.Pnp.TransportName.Buffer = (PWCHAR)(responseMessage + 1);
requestMessage->Message.Pnp.Bind = Bind;
//
// Send the name of the transport of interest to Xactsrv
//
requestMessage->Message.Pnp.TransportName.Length = DeviceName->Length;
requestMessage->Message.Pnp.TransportName.MaximumLength = DeviceName->Length + sizeof( WCHAR );
RtlCopyMemory( requestMessage->Message.Pnp.TransportName.Buffer,
DeviceName->Buffer,
DeviceName->Length
);
//
// Normalize the buffer pointer so xactsrv can rebase it
//
requestMessage->Message.Pnp.TransportName.Buffer =
(PWSTR)((PUCHAR)requestMessage->Message.Pnp.TransportName.Buffer + SrvXsPortMemoryDelta);
requestMessage->PortMessage.u1.s1.DataLength =
(USHORT)( sizeof(*requestMessage) - sizeof(PORT_MESSAGE) );
requestMessage->PortMessage.u1.s1.TotalLength = sizeof(*requestMessage);
requestMessage->PortMessage.u2.ZeroInit = 0;
requestMessage->PortMessage.u2.s2.Type = LPC_KERNELMODE_MESSAGE;
requestMessage->MessageType = XACTSRV_MESSAGE_PNP;
//
// Send the message to XACTSRV
//
IF_DEBUG( PNP ) {
KdPrint(( "SRV: Sending PNP %sbind request for %wZ to SRVSVC\n",
requestMessage->Message.Pnp.Bind ? "" : "un", DeviceName
));
}
status = NtRequestWaitReplyPort(
SrvXsPortHandle,
(PPORT_MESSAGE)requestMessage,
(PPORT_MESSAGE)responseMessage
);
IF_DEBUG( PNP ) {
if( !NT_SUCCESS( status ) ) {
KdPrint(( "SRV: PNP response from xactsrv status %X\n", status ));
}
}
SrvXsFreeHeap( requestMessage );
}
VOID
SrvXsDisconnect ( )
{
NTSTATUS status;
PAGED_CODE( );
//
// Acquire exclusive access to the port resource, to prevent new
// requests from being started.
//
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsDisconnect: Xactsrv disconnect called.\n"));
}
ExAcquireResourceExclusiveLite( &SrvXsResource, TRUE );
SrvXsActive = FALSE;
SrvXsFreeSharedMemory();
ExReleaseResourceLite( &SrvXsResource );
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsDisconnect: SrvXsResource released.\n"));
}
return;
} // SrvXsDisconnect
VOID
SrvXsFreeSharedMemory (
VOID
)
/*++
Routine Description:
This routine frees the xactsrv shared memory. SrvXsResource assumed
held exclusive.
Arguments:
none.
Return Value:
TRUE if xactsrv memory was freed, FALSE otherwise.
--*/
{
PAGED_CODE( );
//
// Free up memory only if we don't have any transactions using the
// shared memory.
//
if ( SrvXsSharedMemoryReference == 0 ) {
if ( SrvXsPortMemoryHeap != NULL ) {
RtlDestroyHeap( SrvXsPortMemoryHeap );
SrvXsPortMemoryHeap = NULL;
}
if ( SrvXsSectionHandle != NULL ) {
SrvNtClose( SrvXsSectionHandle, FALSE );
SrvXsSectionHandle = NULL;
}
if ( SrvXsPortHandle != NULL ) {
SrvNtClose( SrvXsPortHandle, FALSE );
SrvXsPortHandle = NULL;
}
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsFreeSharedMemory: Xactsrv memory freed.\n" ));
}
} else {
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsFreeSharedMemory: Active transactions %d.\n",
SrvXsSharedMemoryReference ));
}
}
return;
} // SrvXsFreeSharedMemory
PVOID
SrvXsAllocateHeap (
IN ULONG SizeOfAllocation OPTIONAL,
OUT PNTSTATUS Status
)
/*++
Routine Description:
This routine allocates heap from the Xs shared memory.
Arguments:
SizeOfAllocation - if specified, the number of bytes to allocate.
if zero, no memory will be allocated.
Status - the status of the request.
Return Value:
Address of the allocated memory. NULL, if no memory is allocated.
--*/
{
PVOID heapAllocated = NULL;
PAGED_CODE( );
*Status = STATUS_SUCCESS;
//
// Check that XACTSRV is active. This must be done while holding
// the resource.
//
ExAcquireResourceExclusiveLite( &SrvXsResource, TRUE );
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsAllocateHeap: SrvXsResource acquired.\n"));
}
if ( !SrvXsActive ) {
IF_DEBUG(ERRORS) {
KdPrint(( "SrvXsAllocateHeap: XACTSRV is not active.\n" ));
}
ExReleaseResourceLite( &SrvXsResource );
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsAllocateHeap: SrvXsResource released.\n"));
}
*Status = STATUS_NOT_SUPPORTED;
return NULL;
}
//
// Increment reference to our shared memory.
//
SrvXsSharedMemoryReference++;
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsAllocateHeap: Incremented transaction count = %d.\n",
SrvXsSharedMemoryReference
));
}
//
// If SizeOfAllocation == 0, then the caller does not want any heap
// allocated and only wants to have the lock held.
//
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsAllocateHeap: Heap to allocate %d bytes.\n",
SizeOfAllocation
));
}
if ( SizeOfAllocation > 0 ) {
heapAllocated = RtlAllocateHeap(
SrvXsPortMemoryHeap,
HEAP_NO_SERIALIZE,
SizeOfAllocation
);
if ( heapAllocated == NULL ) {
IF_DEBUG(ERRORS) {
KdPrint(( "SrvXsAllocateHeap: RtlAllocateHeap failed "
"to allocate %d bytes.\n",
SizeOfAllocation
));
}
*Status = STATUS_INSUFF_SERVER_RESOURCES;
}
}
//
// Release the resource.
//
ExReleaseResourceLite( &SrvXsResource );
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsAllocateHeap: SrvXsResource released.\n"));
}
return heapAllocated;
} // SrvXsAllocateHeap
VOID
SrvXsFreeHeap (
IN PVOID MemoryToFree OPTIONAL
)
/*++
Routine Description:
This routine frees heap allocated through SrvXsAllocateHeap.
Arguments:
MemoryToFree - pointer to the memory to be freed. If NULL, no memory
is freed.
Return Value:
none.
--*/
{
PAGED_CODE( );
//
// We need exclusive access to the resource in order to free
// heap and decrement the reference count.
//
ExAcquireResourceExclusiveLite( &SrvXsResource, TRUE );
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsFreeHeap: SrvXsResource acquired.\n"));
}
//
// Free the allocated heap (if any).
//
if ( MemoryToFree != NULL ) {
RtlFreeHeap( SrvXsPortMemoryHeap, 0, MemoryToFree );
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsFreeHeap: Heap %p freed.\n", MemoryToFree ));
}
}
//
// Decrement the shared memory reference count, and check whether XS
// shutdown is in progress. If so, complete XS cleanup if the
// reference count reaches 0.
//
ASSERT( SrvXsSharedMemoryReference > 0 );
SrvXsSharedMemoryReference--;
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsFreeHeap: Decrement transaction count = %d.\n",
SrvXsSharedMemoryReference
));
}
//
// If SrvXsActive is FALSE, XACTSRV cleanup is in progress.
//
if ( !SrvXsActive ) {
SrvXsFreeSharedMemory( );
}
//
// Release the resource.
//
ExReleaseResourceLite( &SrvXsResource );
IF_DEBUG(XACTSRV) {
KdPrint(( "SrvXsFreeHeap: SrvXsResource released.\n"));
}
return;
} // SrvXsFreeHeap
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