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WindowsXP-SP1/ds/nw/nwlib/nds32.c
Microsoft f7ca35dddd First commit
2020-09-30 16:53:49 +02:00

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/*++
Copyright (c) 1995 Microsoft Corporation
Module Name:
Nds32.c
Abstract:
This module implements functions to Read, Add, Modify, and Remove
NDS Objects and Attributes using the Microsoft Netware redirector.
Author:
Glenn Curtis [GlennC] 04-Jan-1996 - New NDS function implementations
Glenn Curtis [GlennC] 24-Apr-1996 - Added schema APIs
Glenn Curtis [GlennC] 20-Jun-1996 - Added search API
Felix Wong [t-felixw] 24-Sep-1995 - Added Win95 Support
Glenn Curtis [GlennC] 20-Nov-1996 - Improved search API
Glenn Curtis [GlennC] 02-Jan-1997 - Added rename object API
Tommy Evans [tommye] 21-Apr-2000 - Moved the NDS_OBJECT typedef out and
renamed to NDS_OBJECT_PRIV.
--*/
#include <procs.h>
#include <nds32.h>
#include <align.h>
#include <nwapi32.h>
#include <nwpkstr.h>
#ifdef WIN95
#include <msnwapi.h>
#include <utils95.h>
#include <ndsapi95.h>
#endif
/* Definitions */
#define NDS_SIGNATURE 0x6E656C67 /* glen */
#define ONE_KB 1024
#define TWO_KB (ONE_KB*2)
#define FOUR_KB (ONE_KB*4)
#define EIGHT_KB (ONE_KB*8)
#define SIXTEEN_KB (ONE_KB*16)
#define THIRY_TWO_KB (ONE_KB*32)
#define SIXTY_FOUR_KB (ONE_KB*64)
#define ONE_TWENTY_EIGHT_KB (ONE_KB*128)
#define NDS_MAX_BUFFER (ONE_KB*63)
#define NDS_SEARCH_ENTRY 0
#define NDS_SEARCH_SUBORDINATES 1
#define NDS_SEARCH_SUBTREE 2
#define NDS_DEREF_ALIASES 0x00000000
#define NDS_DONT_DEREF_ALIASES 0x00010000
/* NetWare NDS NCP function identifiers */
#define NETWARE_NDS_FUNCTION_RESOLVE_NAME 0x00000001
#define NETWARE_NDS_FUNCTION_READ_OBJECT 0x00000003
#define NETWARE_NDS_FUNCTION_LIST 0x00000005
#define NETWARE_NDS_FUNCTION_SEARCH 0x00000006
#define NETWARE_NDS_FUNCTION_ADD_OBJECT 0x00000007
#define NETWARE_NDS_FUNCTION_REMOVE_OBJECT 0x00000008
#define NETWARE_NDS_FUNCTION_MODIFY_OBJECT 0x00000009
#define NETWARE_NDS_FUNCTION_MODIFY_RDN 0x0000000A
#define NETWARE_NDS_FUNCTION_DEFINE_ATTR 0x0000000B
#define NETWARE_NDS_FUNCTION_READ_ATTR_DEF 0x0000000C
#define NETWARE_NDS_FUNCTION_REMOVE_ATTR_DEF 0x0000000D
#define NETWARE_NDS_FUNCTION_DEFINE_CLASS 0x0000000E
#define NETWARE_NDS_FUNCTION_READ_CLASS_DEF 0x0000000F
#define NETWARE_NDS_FUNCTION_MODIFY_CLASS 0x00000010
#define NETWARE_NDS_FUNCTION_REMOVE_CLASS_DEF 0x00000011
#define NETWARE_NDS_FUNCTION_LIST_CONT_CLASSES 0x00000012
#define NETWARE_NDS_FUNCTION_GET_EFFECTIVE_RIGHTS 0x00000013
#define NETWARE_NDS_FUNCTION_BEGIN_MOVE_OBJECT 0x0000002A
#define NETWARE_NDS_FUNCTION_FINISH_MOVE_OBJECT 0x0000002B
#define NETWARE_NDS_FUNCTION_GET_SERVER_ADDRESS 0x00000035
/* Data structure definitions */
typedef struct
{
DWORD dwBufferId;
DWORD dwOperation;
//
// About the request buffer
//
DWORD dwRequestBufferSize;
DWORD dwRequestAvailableBytes;
DWORD dwNumberOfRequestEntries;
DWORD dwLengthOfRequestData;
//
// The request buffer
//
LPBYTE lpRequestBuffer;
//
// About the reply buffer
//
DWORD dwReplyBufferSize;
DWORD dwReplyAvailableBytes;
DWORD dwNumberOfReplyEntries;
DWORD dwLengthOfReplyData;
//
// More about the reply buffer
//
DWORD dwReplyInformationType;
//
// The reply buffer
//
LPBYTE lpReplyBuffer;
//
// About the index buffer
//
DWORD dwIndexBufferSize;
DWORD dwIndexAvailableBytes;
DWORD dwNumberOfIndexEntries;
DWORD dwLengthOfIndexData;
//
// More about the index buffer
//
DWORD dwCurrentIndexEntry;
//
// The index buffer
//
LPBYTE lpIndexBuffer;
//
// About the syntax buffer
//
DWORD dwSyntaxBufferSize;
DWORD dwSyntaxAvailableBytes;
DWORD dwNumberOfSyntaxEntries;
DWORD dwLengthOfSyntaxData;
//
// The syntax buffer
//
LPBYTE lpSyntaxBuffer;
//
// A place to keep the search from object path ...
//
WCHAR szPath[NDS_MAX_NAME_CHARS + 1];
} NDS_BUFFER, * LPNDS_BUFFER;
/* Local Function Definitions */
VOID
PrepareAddEntry(
LPBYTE lpTempEntry,
UNICODE_STRING AttributeName,
DWORD dwSyntaxID,
LPBYTE lpAttributeValues,
DWORD dwValueCount,
LPDWORD lpdwLengthInBytes );
VOID
PrepareModifyEntry(
LPBYTE lpTempEntry,
UNICODE_STRING AttributeName,
DWORD dwSyntaxID,
DWORD dwAttrModificationOperation,
LPBYTE lpAttributeValues,
DWORD dwValueCount,
LPDWORD lpdwLengthInBytes );
VOID
PrepareReadEntry(
LPBYTE lpTempEntry,
UNICODE_STRING AttributeName,
LPDWORD lpdwLengthInBytes );
DWORD
CalculateValueDataSize(
DWORD dwSyntaxId,
LPBYTE lpAttributeValues,
DWORD dwValueCount );
VOID
AppendValueToEntry(
LPBYTE lpBuffer,
DWORD dwSyntaxId,
LPBYTE lpAttributeValues,
DWORD dwValueCount,
LPDWORD lpdwLengthInBytes );
DWORD
MapNetwareErrorCode(
DWORD dwNetwareError );
DWORD
IndexReadAttrDefReplyBuffer(
LPNDS_BUFFER lpNdsBuffer );
DWORD
IndexReadClassDefReplyBuffer(
LPNDS_BUFFER lpNdsBuffer );
DWORD
IndexReadObjectReplyBuffer(
LPNDS_BUFFER lpNdsBuffer );
DWORD
IndexReadNameReplyBuffer(
LPNDS_BUFFER lpNdsBuffer );
DWORD
IndexSearchObjectReplyBuffer(
LPNDS_BUFFER lpNdsBuffer );
DWORD
SizeOfASN1Structure(
LPBYTE * lppRawBuffer,
DWORD dwSyntaxId );
DWORD
ParseASN1ValueBlob(
LPBYTE RawDataBuffer,
DWORD dwSyntaxId,
DWORD dwNumberOfValues,
LPBYTE SyntaxStructure );
DWORD
ParseStringListBlob(
LPBYTE RawDataBuffer,
DWORD dwNumberOfStrings,
LPBYTE SyntaxStructure );
DWORD
ReadAttrDef_AllAttrs(
IN HANDLE hTree,
IN DWORD dwInformationType,
OUT HANDLE lphOperationData );
DWORD
ReadAttrDef_SomeAttrs(
IN HANDLE hTree,
IN DWORD dwInformationType,
IN OUT HANDLE lphOperationData );
DWORD
ReadClassDef_AllClasses(
IN HANDLE hTree,
IN DWORD dwInformationType,
OUT HANDLE lphOperationData );
DWORD
ReadClassDef_SomeClasses(
IN HANDLE hTree,
IN DWORD dwInformationType,
IN OUT HANDLE lphOperationData );
DWORD
ReadObject_AllAttrs(
IN HANDLE hObject,
IN DWORD dwInformationType,
OUT HANDLE * lphOperationData );
DWORD
ReadObject_SomeAttrs(
IN HANDLE hObject,
IN DWORD dwInformationType,
IN OUT HANDLE * lphOperationData );
DWORD
Search_AllAttrs(
IN HANDLE hStartFromObject,
IN DWORD dwInformationType,
IN DWORD dwScope,
IN BOOL fDerefAliases,
IN LPQUERY_TREE lpQueryTree,
IN OUT LPDWORD lpdwIterHandle,
OUT HANDLE * lphOperationData );
DWORD
Search_SomeAttrs(
IN HANDLE hStartFromObject,
IN DWORD dwInformationType,
IN DWORD dwScope,
IN BOOL fDerefAliases,
IN LPQUERY_TREE lpQueryTree,
IN OUT LPDWORD lpdwIterHandle,
IN OUT HANDLE * lphOperationData );
DWORD
GetFirstNdsSubTreeEntry(
OUT LPNDS_OBJECT_PRIV lpNdsObject,
IN DWORD BufferSize );
DWORD
GetNextNdsSubTreeEntry(
OUT LPNDS_OBJECT_PRIV lpNdsObject );
VOID
GetSubTreeData(
IN DWORD NdsRawDataPtr,
OUT LPDWORD lpdwEntryId,
OUT LPDWORD lpdwSubordinateCount,
OUT LPDWORD lpdwModificationTime,
OUT LPDWORD lpdwClassNameLen,
OUT LPWSTR * szClassName,
OUT LPDWORD lpdwObjectNameLen,
OUT LPWSTR * szObjectName );
LPBYTE
GetSearchResultData( IN LPBYTE lpResultBufferPtr,
OUT LPDWORD lpdwFlags,
OUT LPDWORD lpdwSubordinateCount,
OUT LPDWORD lpdwModificationTime,
OUT LPDWORD lpdwClassNameLen,
OUT LPWSTR * szClassName,
OUT LPDWORD lpdwObjectNameLen,
OUT LPWSTR * szObjectName,
OUT LPDWORD lpdwEntryInfo1,
OUT LPDWORD lpdwEntryInfo2 );
DWORD
WriteObjectToBuffer(
IN OUT LPBYTE * FixedPortion,
IN OUT LPWSTR * EndOfVariableData,
IN LPWSTR ObjectFullName,
IN LPWSTR ObjectName,
IN LPWSTR ClassName,
IN DWORD EntryId,
IN DWORD ModificationTime,
IN DWORD SubordinateCount,
IN DWORD NumberOfAttributes,
IN LPNDS_ATTR_INFO lpAttributeInfos );
DWORD
VerifyBufferSize(
IN LPBYTE lpRawBuffer,
IN DWORD dwBufferSize,
IN DWORD dwSyntaxID,
IN DWORD dwNumberOfValues,
OUT LPDWORD lpdwLength );
DWORD
VerifyBufferSizeForStringList(
IN DWORD dwBufferSize,
IN DWORD dwNumberOfValues,
OUT LPDWORD lpdwLength );
DWORD
WriteQueryTreeToBuffer(
IN LPQUERY_TREE lpQueryTree,
IN LPNDS_BUFFER lpNdsBuffer );
DWORD
WriteQueryNodeToBuffer(
IN LPQUERY_NODE lpQueryNode,
IN LPNDS_BUFFER lpNdsBuffer );
DWORD
NwNdsGetServerDN(
IN HANDLE hTree,
OUT LPWSTR szServerDN );
DWORD
AllocateOrIncreaseSyntaxBuffer(
IN LPNDS_BUFFER lpNdsBuffer );
DWORD
AllocateOrIncreaseRequestBuffer(
IN LPNDS_BUFFER lpNdsBuffer );
//
// Flags used for the function ParseNdsUncPath()
//
#define PARSE_NDS_GET_TREE_NAME 0
#define PARSE_NDS_GET_PATH_NAME 1
#define PARSE_NDS_GET_OBJECT_NAME 2
WORD
ParseNdsUncPath( IN OUT LPWSTR * Result,
IN LPWSTR ObjectPathName,
IN DWORD flag );
/* Function Implementations */
DWORD
NwNdsAddObject(
IN HANDLE hParentObject,
IN LPWSTR szObjectName,
IN HANDLE hOperationData )
/*
NwNdsAddObject()
This function is used to add a leaf object to an NDS directory tree.
Arguments:
HANDLE hParentObject - A handle to the parent object in
the directory tree to add a new leaf to. Handle is
obtained by calling NwNdsOpenObject.
LPWSTR szObjectName - The directory name that the new leaf
object will be known by.
HANDLE hOperationData - A buffer containing a list of
attributes and values to create the new object. This
buffer is manipulated by the following functions:
NwNdsCreateBuffer (NDS_OBJECT_ADD),
NwNdsPutInBuffer, and NwNdsFreeBuffer.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD nwstatus;
NTSTATUS ntstatus;
DWORD dwReplyLength;
BYTE NdsReply[NDS_BUFFER_SIZE];
LPNDS_BUFFER lpNdsBuffer = (LPNDS_BUFFER) hOperationData;
LPNDS_OBJECT_PRIV lpNdsParentObject = (LPNDS_OBJECT_PRIV) hParentObject;
UNICODE_STRING ObjectName;
if ( lpNdsBuffer == NULL ||
lpNdsParentObject == NULL ||
szObjectName == NULL ||
lpNdsBuffer->dwBufferId != NDS_SIGNATURE ||
lpNdsBuffer->dwOperation != NDS_OBJECT_ADD ||
lpNdsParentObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
RtlInitUnicodeString( &ObjectName, szObjectName );
ntstatus =
FragExWithWait(
lpNdsParentObject->NdsTree,
NETWARE_NDS_FUNCTION_ADD_OBJECT,
NdsReply,
NDS_BUFFER_SIZE,
&dwReplyLength,
"DDDSDr",
0, // Version
0, // Flags
lpNdsParentObject->ObjectId,
&ObjectName,
lpNdsBuffer->dwNumberOfRequestEntries,
lpNdsBuffer->lpRequestBuffer, // Object attributes to be added
(WORD)lpNdsBuffer->dwLengthOfRequestData // Length of data
);
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsAddObject: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsAddObject: The add name response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
DWORD
NwNdsAddAttributeToClass(
IN HANDLE hTree,
IN LPWSTR szClassName,
IN LPWSTR szAttributeName )
/*
NwNdsAddAttributeToClass()
This function is used to modify the schema definition of a class by adding
an optional attribute to a particular class. Modification of existing NDS
class defintions is limited to only adding additional optional attributes.
Arguments:
HANDLE hTree - A handle to the directory tree to be
manipulated. Handle is obtained by calling
NwNdsOpenObject.
LPWSTR szClassName - The name of the class definition to be
modified.
LPWSTR szAttributeName - The name of the attribute to be added
as an optional attribute to the class defintion in the
schema.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD nwstatus;
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_SUCCESS;
DWORD dwReplyLength;
BYTE NdsReply[NDS_BUFFER_SIZE];
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hTree;
UNICODE_STRING ClassName;
UNICODE_STRING AttributeName;
if ( szAttributeName == NULL ||
szClassName == NULL ||
lpNdsObject == NULL ||
lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
RtlInitUnicodeString( &ClassName, szClassName );
RtlInitUnicodeString( &AttributeName, szAttributeName );
ntstatus =
FragExWithWait(
lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_MODIFY_CLASS,
NdsReply,
NDS_BUFFER_SIZE,
&dwReplyLength,
"DSDS",
0, // Version
&ClassName,
1, // Number of attributes
&AttributeName
);
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsAddAttributeToClass: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsAddAttributeToClass: The modify class definition response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
DWORD
NwNdsChangeUserPassword(
IN HANDLE hUserObject,
IN LPWSTR szOldPassword,
IN LPWSTR szNewPassword )
/*
NwNdsChangeUserPassword()
This function is used to change the password for a given user object
in a NDS directory tree.
Arguments:
HANDLE hUserObject - A handle to a specific user object in
the directory tree to change the password on. Handle
is obtained by calling NwNdsOpenObject.
LPWSTR szOldPassword - The current password set on the user
object hUserObject.
- OR -
If NwNdsChangeUserPassword is called from a client with
administrative priveleges to the specified user object
identified by hUserObject, then the szOldPassword
value can be blank (L""). This way resetting the user
password to szNewPassword.
LPWSTR szNewPassword - The new password to be set on the user
object hUserObject.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_UNSUCCESSFUL;
UNICODE_STRING TreeNameStr;
UNICODE_STRING UserNameStr;
UNICODE_STRING OldPasswordStr;
UNICODE_STRING NewPasswordStr;
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hUserObject;
DWORD tempStrLen = 0;
LPWSTR tempStr = NULL;
tempStrLen = ParseNdsUncPath( (LPWSTR *) &tempStr,
lpNdsObject->szContainerName,
PARSE_NDS_GET_TREE_NAME );
TreeNameStr.Buffer = tempStr;
TreeNameStr.Length = (WORD) tempStrLen;
TreeNameStr.MaximumLength = (WORD) tempStrLen;
tempStrLen = ParseNdsUncPath( (LPWSTR *) &tempStr,
lpNdsObject->szContainerName,
PARSE_NDS_GET_PATH_NAME );
#ifndef WIN95
UserNameStr.Buffer = tempStr;
UserNameStr.Length = (WORD) tempStrLen;
UserNameStr.MaximumLength = (WORD) tempStrLen;
RtlInitUnicodeString( &OldPasswordStr, szOldPassword );
RtlInitUnicodeString( &NewPasswordStr, szNewPassword );
ntstatus = NwNdsChangePassword( lpNdsObject->NdsTree,
&TreeNameStr,
&UserNameStr,
&OldPasswordStr,
&NewPasswordStr );
#else
{
LPSTR pszUser = NULL;
LPSTR pszOldPasswd = NULL;
LPSTR pszNewPasswd = NULL;
NW_STATUS nwstatus;
if (!(pszUser = AllocateAnsiString(tempStr))) {
ntstatus = STATUS_NO_MEMORY;
goto Exit;
}
if (!(pszOldPasswd = AllocateAnsiString(szOldPassword))) {
ntstatus = STATUS_NO_MEMORY;
goto Exit;
}
if (!(pszNewPasswd= AllocateAnsiString(szNewPassword))) {
ntstatus = STATUS_NO_MEMORY;
goto Exit;
}
nwstatus = NDSChangePassword( pszUser,
pszOldPasswd,
pszNewPasswd );
ntstatus = MapNwToNtStatus(nwstatus);
Exit:
if (pszUser)
FreeAnsiString(pszUser);
if (pszOldPasswd)
FreeAnsiString(pszOldPasswd);
if (pszNewPasswd)
FreeAnsiString(pszNewPasswd);
}
#endif
if ( ntstatus != STATUS_SUCCESS )
{
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
}
return status;
}
DWORD
NwNdsCloseObject(
IN HANDLE hObject )
/*
NwNdsCloseObject()
This function is used to close the handle used to manipulate an object
in an NDS directory tree. The handle must be one Opened by NwNdsOpenObject.
Arguments:
HANDLE lphObject - The handle of the object to be closed.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hObject;
if ( lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
if ( lpNdsObject )
{
if ( lpNdsObject->NdsTree )
CloseHandle( lpNdsObject->NdsTree );
if ( lpNdsObject->NdsRawDataBuffer )
{
(void) LocalFree( (HLOCAL) lpNdsObject->NdsRawDataBuffer );
lpNdsObject->NdsRawDataBuffer = 0;
lpNdsObject->NdsRawDataSize = 0;
lpNdsObject->NdsRawDataId = INITIAL_ITERATION;
lpNdsObject->NdsRawDataCount = 0;
}
(void) LocalFree( (HLOCAL) lpNdsObject );
}
else
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
return NO_ERROR;
}
DWORD
NwNdsCreateBuffer(
IN DWORD dwOperation,
OUT HANDLE * lphOperationData )
/*
NwNdsCreateBuffer()
This function is used to create a buffer used to describe object
transactions to a specific object in an NDS directory tree. This routine
allocates memory and is automatically resized as needed during calls
to NwNdsPutInBuffer. This buffer must be freed with NwNdsFreeBuffer.
Arguments:
DWORD dwOperation - Indicates how buffer is to be utilized.
Use defined values NDS_OBJECT_ADD, NDS_OBJECT_MODIFY,
NDS_OBJECT_READ, NDS_SCHEMA_DEFINE_CLASS,
NDS_SCHEMA_READ_ATTR_DEF, NDS_SCHEMA_READ_CLASS_DEF,
NDS_OBJECT_LIST_SUBORDINATES, NDS_SEARCH.
HANDLE * lphOperationData - Address of a HANDLE handle to
receive created buffer.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
LPNDS_BUFFER lpNdsBuffer = NULL;
DWORD dwSizeOfBuffer = TWO_KB; // Initial size, grow as needed.
switch( dwOperation )
{
case NDS_OBJECT_ADD:
case NDS_OBJECT_MODIFY:
case NDS_OBJECT_READ:
case NDS_SCHEMA_DEFINE_CLASS:
case NDS_SCHEMA_READ_ATTR_DEF:
case NDS_SCHEMA_READ_CLASS_DEF:
case NDS_OBJECT_LIST_SUBORDINATES:
case NDS_SEARCH:
break;
default:
#if DBG
KdPrint(( "NDS32: NwNdsCreateBuffer parameter dwOperation unknown 0x%.8X\n", dwOperation ));
ASSERT( FALSE );
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Allocate memory for the buffer.
//
lpNdsBuffer =
(LPNDS_BUFFER) LocalAlloc( LPTR, sizeof(NDS_BUFFER) );
if ( lpNdsBuffer == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
//
// Initialize the contents of the header structure.
//
lpNdsBuffer->dwBufferId = NDS_SIGNATURE;
lpNdsBuffer->dwOperation = dwOperation;
if ( dwOperation == NDS_OBJECT_LIST_SUBORDINATES )
{
lpNdsBuffer->dwIndexBufferSize = dwSizeOfBuffer;
lpNdsBuffer->dwIndexAvailableBytes = dwSizeOfBuffer;
}
else
{
lpNdsBuffer->dwRequestBufferSize = dwSizeOfBuffer;
lpNdsBuffer->dwRequestAvailableBytes = dwSizeOfBuffer;
}
//
// NOTE: The following are set to zero by LPTR
//
// lpNdsBuffer->dwNumberOfRequestEntries = 0;
// lpNdsBuffer->dwLengthOfRequestData = 0;
// lpNdsBuffer->dwReplyBufferSize = 0;
// lpNdsBuffer->dwReplyAvailableBytes = 0;
// lpNdsBuffer->dwNumberOfReplyEntries = 0;
// lpNdsBuffer->dwLengthOfReplyData = 0;
// lpNdsBuffer->dwReplyInformationType = 0;
// lpNdsBuffer->lpReplyBuffer = NULL;
// lpNdsBuffer->dwNumberOfIndexEntries = 0;
// lpNdsBuffer->dwLengthOfIndexData = 0;
// lpNdsBuffer->dwCurrentIndexEntry = 0;
// lpNdsBuffer->dwSyntaxBufferSize = 0;
// lpNdsBuffer->dwSyntaxAvailableBytes = 0;
// lpNdsBuffer->dwNumberOfSyntaxEntries = 0;
// lpNdsBuffer->dwLengthOfSyntaxData = 0;
// lpNdsBuffer->lpSyntaxBuffer = NULL;
//
// Now allocate the data buffer.
//
if ( dwOperation == NDS_OBJECT_LIST_SUBORDINATES )
{
lpNdsBuffer->lpIndexBuffer =
(LPBYTE) LocalAlloc( LPTR, dwSizeOfBuffer );
if ( lpNdsBuffer->lpIndexBuffer == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
(void) LocalFree((HLOCAL) lpNdsBuffer);
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
}
else
{
lpNdsBuffer->lpRequestBuffer =
(LPBYTE) LocalAlloc( LPTR, dwSizeOfBuffer );
if ( lpNdsBuffer->lpRequestBuffer == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
(void) LocalFree((HLOCAL) lpNdsBuffer);
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
}
*lphOperationData = (HANDLE) lpNdsBuffer;
return NO_ERROR;
}
DWORD
NwNdsCreateQueryNode(
IN DWORD dwOperation,
IN LPVOID lpLValue,
IN DWORD dwSyntaxId,
IN LPVOID lpRValue,
OUT LPQUERY_NODE * lppQueryNode
)
/*
NwNdsCreateQueryNode()
This function is used to generate a tree node that is part of a query
to be used with the function NwNdsSearch.
Arguments:
DWORD dwOperation - Indicates the type of node to create
for a search query. Use one of the defined values
below:
NDS_QUERY_OR
NDS_QUERY_AND :
These operations must have both lpLValue and
lpRValue pointing to a QUERY_NODE structure.
In this case the dwSyntaxId value is ignored.
NDS_QUERY_NOT :
This operation must have lpLValue pointing to a
QUERY_NODE structure and lpRValue set to NULL.
In this case the dwSyntaxId value is ignored.
NDS_QUERY_EQUAL
NDS_QUERY_GE
NDS_QUERY_LE
NDS_QUERY_APPROX :
These operations must have lpLValue pointing to
a LPWSTR containing the name of an NDS attribute,
and lpRValue pointing to an ASN1 structure defined
in NdsSntx.h. dwSyntaxId must be set to the syntax
identifier of the ASN1 structure pointed to by
lpRValue.
NDS_QUERY_PRESENT :
This operation must have lpLValue pointing to a
LPWSTR containing the name of an NDS attribute,
and lpRValue set to NULL. In this case the
dwSyntaxId value is ignored.
LPVOID lpLValue - A pointer to either a QUERY_NODE structure
or a LPWSTR depending on the value for dwOperation.
DWORD dwSyntaxId - The syntax identifier of the ASN1
structure pointed to by lpRValue for the dwOperations
NDS_QUERY_EQUAL, NDS_QUERY_GE, NDS_QUERY_LE, or
NDS_QUERY_APPROX. For other dwOperation values, this
is ignored.
LPVOID lpRValue - A pointer to either a QUERY_NODE structure,
an ASN1 structure, or NULL, depending on the value for
dwOperation.
LPQUERY_NODE * lppQueryNode - Address of a LPQUERY_NODE to receive
a pointer to created node.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
LPWSTR szAttributeName;
DWORD dwAttributeNameLen;
LPWSTR szRValueString;
DWORD dwRValueStringLen;
switch( dwOperation )
{
case NDS_QUERY_OR :
case NDS_QUERY_AND :
if ( lpLValue == NULL || lpRValue == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateQueryNode was not passed a pointer to an L or R value.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
*lppQueryNode = (LPQUERY_NODE) LocalAlloc( LPTR,
sizeof(QUERY_NODE) );
if ( *lppQueryNode == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateQueryNode LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
(*lppQueryNode)->dwOperation = dwOperation;
(*lppQueryNode)->dwSyntaxId = NDS_NO_MORE_ITERATIONS;
(*lppQueryNode)->lpLVal = lpLValue;
(*lppQueryNode)->lpRVal = lpRValue;
break;
case NDS_QUERY_NOT :
if ( lpLValue == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateQueryNode was not passed a pointer to an L value.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
*lppQueryNode = (LPQUERY_NODE) LocalAlloc( LPTR,
sizeof(QUERY_NODE) );
if ( *lppQueryNode == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateQueryNode LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
(*lppQueryNode)->dwOperation = dwOperation;
(*lppQueryNode)->dwSyntaxId = NDS_NO_MORE_ITERATIONS;
(*lppQueryNode)->lpLVal = lpLValue;
(*lppQueryNode)->lpRVal = NULL;
break;
case NDS_QUERY_EQUAL :
case NDS_QUERY_GE :
case NDS_QUERY_LE :
case NDS_QUERY_APPROX :
switch( dwSyntaxId )
{
case NDS_SYNTAX_ID_1 :
case NDS_SYNTAX_ID_2 :
case NDS_SYNTAX_ID_3 :
case NDS_SYNTAX_ID_4 :
case NDS_SYNTAX_ID_5 :
case NDS_SYNTAX_ID_10 :
case NDS_SYNTAX_ID_20 :
//
// This syntax is in the form of a LPWSTR.
//
szAttributeName = (LPWSTR) lpLValue;
dwAttributeNameLen = ROUND_UP_COUNT(
( wcslen( szAttributeName ) + 1 ) *
sizeof(WCHAR),
ALIGN_DWORD );
szRValueString = ((LPASN1_TYPE_1) lpRValue)->DNString;
dwRValueStringLen = ROUND_UP_COUNT(
( wcslen( szRValueString ) + 1 ) *
sizeof(WCHAR),
ALIGN_DWORD );
*lppQueryNode = (LPQUERY_NODE)
LocalAlloc( LPTR,
sizeof(QUERY_NODE) +
dwAttributeNameLen +
dwRValueStringLen );
if ( *lppQueryNode == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateQueryNode LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
(*lppQueryNode)->dwOperation = dwOperation;
(*lppQueryNode)->dwSyntaxId = dwSyntaxId;
(*lppQueryNode)->lpLVal = *lppQueryNode;
(LPBYTE) (*lppQueryNode)->lpLVal += sizeof(QUERY_NODE);
wcscpy( (LPWSTR) (*lppQueryNode)->lpLVal, szAttributeName );
(*lppQueryNode)->lpRVal = (*lppQueryNode)->lpLVal;
(LPBYTE) (*lppQueryNode)->lpRVal += dwAttributeNameLen;
wcscpy( (LPWSTR) (*lppQueryNode)->lpRVal, szRValueString );
break;
case NDS_SYNTAX_ID_7 :
case NDS_SYNTAX_ID_8 :
case NDS_SYNTAX_ID_22 :
case NDS_SYNTAX_ID_24 :
case NDS_SYNTAX_ID_27 :
//
// This syntax is in the form of a DWORD.
//
szAttributeName = (LPWSTR) lpLValue;
dwAttributeNameLen = ROUND_UP_COUNT(
( wcslen( szAttributeName ) + 1 ) *
sizeof(WCHAR),
ALIGN_DWORD );
*lppQueryNode = (LPQUERY_NODE)
LocalAlloc( LPTR,
sizeof(QUERY_NODE) +
dwAttributeNameLen +
sizeof(ASN1_TYPE_8) );
if ( *lppQueryNode == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateQueryNode LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
(*lppQueryNode)->dwOperation = dwOperation;
(*lppQueryNode)->dwSyntaxId = dwSyntaxId;
(*lppQueryNode)->lpLVal = *lppQueryNode;
(LPBYTE) (*lppQueryNode)->lpLVal += sizeof(QUERY_NODE);
wcscpy( (LPWSTR) (*lppQueryNode)->lpLVal,
szAttributeName );
(*lppQueryNode)->lpRVal = (LPQUERY_NODE)((LPBYTE)((*lppQueryNode)->lpLVal) +
dwAttributeNameLen);
((LPASN1_TYPE_8)(*lppQueryNode)->lpRVal)->Integer =
((LPASN1_TYPE_8)lpRValue)->Integer;
break;
case NDS_SYNTAX_ID_9 :
//
// This syntax is in the form of an Octet String.
//
szAttributeName = (LPWSTR) lpLValue;
dwAttributeNameLen = ROUND_UP_COUNT(
( wcslen( szAttributeName ) + 1 ) *
sizeof(WCHAR),
ALIGN_DWORD );
*lppQueryNode = (LPQUERY_NODE)
LocalAlloc( LPTR,
sizeof(QUERY_NODE) +
dwAttributeNameLen +
sizeof( DWORD ) +
((LPASN1_TYPE_9) lpRValue)->Length + 1 );
if ( *lppQueryNode == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateQueryNode LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
(*lppQueryNode)->dwOperation = dwOperation;
(*lppQueryNode)->dwSyntaxId = dwSyntaxId;
(*lppQueryNode)->lpLVal = *lppQueryNode;
(LPBYTE) (*lppQueryNode)->lpLVal += sizeof(QUERY_NODE);
wcscpy( (LPWSTR) (*lppQueryNode)->lpLVal, szAttributeName );
(*lppQueryNode)->lpRVal = (*lppQueryNode)->lpLVal;
(LPBYTE) (*lppQueryNode)->lpRVal += dwAttributeNameLen;
*((LPDWORD) (*lppQueryNode)->lpRVal) =
((LPASN1_TYPE_9) lpRValue)->Length;
(LPBYTE) (*lppQueryNode)->lpRVal += sizeof( DWORD );
memcpy( (*lppQueryNode)->lpRVal,
((LPASN1_TYPE_9) lpRValue)->OctetString,
((LPASN1_TYPE_9) lpRValue)->Length );
(LPBYTE) (*lppQueryNode)->lpRVal -= sizeof( DWORD );
break;
default :
SetLastError( ERROR_NOT_SUPPORTED );
return (DWORD) UNSUCCESSFUL;
}
break;
case NDS_QUERY_PRESENT :
if ( lpLValue == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateQueryNode was not passed a pointer to an L value.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
szAttributeName = (LPWSTR) lpLValue;
dwAttributeNameLen = ( wcslen( szAttributeName ) + 1 ) *
sizeof(WCHAR);
*lppQueryNode = (LPQUERY_NODE) LocalAlloc( LPTR,
sizeof(QUERY_NODE) +
dwAttributeNameLen );
if ( *lppQueryNode == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateQueryNode LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
(*lppQueryNode)->dwOperation = dwOperation;
(*lppQueryNode)->dwSyntaxId = NDS_NO_MORE_ITERATIONS;
(*lppQueryNode)->lpLVal = (*lppQueryNode);
(LPBYTE) (*lppQueryNode)->lpLVal += sizeof(QUERY_NODE);
wcscpy( (LPWSTR) (*lppQueryNode)->lpLVal, szAttributeName );
(*lppQueryNode)->lpRVal = NULL;
break;
default :
#if DBG
KdPrint(( "NDS32: NwNdsCreateQueryNode was passed an unidentified operation - 0x%.8X.\n", dwOperation ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
return NO_ERROR;
}
DWORD
NwNdsDefineAttribute(
IN HANDLE hTree,
IN LPWSTR szAttributeName,
IN DWORD dwFlags,
IN DWORD dwSyntaxID,
IN DWORD dwLowerLimit,
IN DWORD dwUpperLimit,
IN ASN1_ID asn1ID )
/*
NwNdsDefineAttribute()
This function is used to create an attribute definition in the schema of
NDS tree hTree.
Arguments:
HANDLE hTree - A handle to the directory tree to be
manipulated. Handle is obtained by calling
NwNdsOpenObject.
LPWSTR szAttributeName - The name that the new attribute will
be referred to by.
DWORD dwFlags - Flags values to be set for new attribute
definition. Definitions for flag values are found at
the top of the file Nds32.h.
DWORD dwSyntaxID - The ID of the syntax structure to be use
for the new attribute. Syntax IDs and their associated
structures are defined in the file NdsSntx.h. According
to the NetWare NDS schema spec, there is and always will
be, only 28 (0..27) different syntaxes.
DWORD dwLowerLimit - The lower limit of a sized attribute
(dwFlags value set to NDS_SIZED_ATTR). Can be set to
zero if attribute is not sized.
DWORD dwUpperLimit - The upper limit of a sized attribute
(dwFlags value set to NDS_SIZED_ATTR). Can be set to
zero if attribute is not sized.
ASN1_ID asn1ID - The ASN.1 ID for the attribute. If no
attribute identifier has been registered, a
zero-length octet string is specified.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD nwstatus;
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_SUCCESS;
DWORD dwReplyLength;
BYTE NdsReply[NDS_BUFFER_SIZE];
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hTree;
UNICODE_STRING AttributeName;
if ( szAttributeName == NULL ||
lpNdsObject == NULL ||
lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
RtlInitUnicodeString( &AttributeName, szAttributeName );
ntstatus =
FragExWithWait(
lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_DEFINE_ATTR,
NdsReply,
NDS_BUFFER_SIZE,
&dwReplyLength,
"DDSDDDD",
0, // Version
dwFlags,
&AttributeName,
dwSyntaxID,
dwLowerLimit,
dwUpperLimit,
0 // ASN1 Id
);
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsDefineAttribute: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsDefineAttribute: The define attribute response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
DWORD
NwNdsDefineClass(
IN HANDLE hTree,
IN LPWSTR szClassName,
IN DWORD dwFlags,
IN ASN1_ID asn1ID,
IN HANDLE hSuperClasses,
IN HANDLE hContainmentClasses,
IN HANDLE hNamingAttributes,
IN HANDLE hMandatoryAttributes,
IN HANDLE hOptionalAttributes )
/*
NwNdsDefineClass()
This function is used to create a class definition in the schema of
NDS tree hTree.
Arguments:
HANDLE hTree - A handle to the directory tree to be
manipulated. Handle is obtained by calling
NwNdsOpenObject.
LPWSTR szClassName - The name that the new class will
be referred to by.
DWORD dwFlags - Flags values to be set for new class
definition. Definitions for flag values are found at
the top of the file Nds32.h.
ASN1_ID asn1ID - The ASN.1 ID for the class. If no
class identifier has been registered, a
zero-length octet string is specified.
HANDLE(S) hSuperClasses,
hContainmentClasses,
hNamingAttributes,
hMandatoryAttributes,
hOptionalAttributes -
Handle to buffers that contain class definition
information to create new class in schema.
These handles are manipulated by the following
functions:
NwNdsCreateBuffer (NDS_SCHEMA_DEFINE_CLASS),
NwNdsPutInBuffer, and NwNdsFreeBuffer.
- OR -
Handles can be NULL to indicate that no list
is associated with the specific class defintion
item.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD nwstatus;
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_SUCCESS;
DWORD dwReplyLength;
BYTE NdsReply[NDS_BUFFER_SIZE];
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hTree;
UNICODE_STRING ClassName;
LPNDS_BUFFER lpSuperClasses = (LPNDS_BUFFER) hSuperClasses;
LPNDS_BUFFER lpContainmentClasses = (LPNDS_BUFFER) hContainmentClasses;
LPNDS_BUFFER lpNamingAttributes = (LPNDS_BUFFER) hNamingAttributes;
LPNDS_BUFFER lpMandatoryAttributes = (LPNDS_BUFFER) hMandatoryAttributes;
LPNDS_BUFFER lpOptionalAttributes = (LPNDS_BUFFER) hOptionalAttributes;
DWORD NumberOfSuperClasses = 0;
DWORD NumberOfContainmentClasses = 0;
DWORD NumberOfNamingAttributes = 0;
DWORD NumberOfMandatoryAttributes = 0;
DWORD NumberOfOptionalAttributes = 0;
WORD SuperClassesBufferLength = 0;
WORD ContainmentClassesBufferLength = 0;
WORD NamingAttributesBufferLength = 0;
WORD MandatoryAttributesBufferLength = 0;
WORD OptionalAttributesBufferLength = 0;
LPBYTE SuperClassesBuffer = NULL;
LPBYTE ContainmentClassesBuffer = NULL;
LPBYTE NamingAttributesBuffer = NULL;
LPBYTE MandatoryAttributesBuffer = NULL;
LPBYTE OptionalAttributesBuffer = NULL;
if ( szClassName == NULL ||
lpNdsObject == NULL ||
lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
if ( lpSuperClasses )
{
if ( lpSuperClasses->dwBufferId != NDS_SIGNATURE ||
lpSuperClasses->dwOperation != NDS_SCHEMA_DEFINE_CLASS )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
NumberOfSuperClasses = lpSuperClasses->dwNumberOfRequestEntries,
SuperClassesBuffer = lpSuperClasses->lpRequestBuffer,
SuperClassesBufferLength = (WORD)lpSuperClasses->dwLengthOfRequestData;
}
if ( lpContainmentClasses )
{
if ( lpContainmentClasses->dwBufferId != NDS_SIGNATURE ||
lpContainmentClasses->dwOperation != NDS_SCHEMA_DEFINE_CLASS )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
NumberOfContainmentClasses =
lpContainmentClasses->dwNumberOfRequestEntries,
ContainmentClassesBuffer =
lpContainmentClasses->lpRequestBuffer,
ContainmentClassesBufferLength =
(WORD)lpContainmentClasses->dwLengthOfRequestData;
}
if ( lpNamingAttributes )
{
if ( lpNamingAttributes->dwBufferId != NDS_SIGNATURE ||
lpNamingAttributes->dwOperation != NDS_SCHEMA_DEFINE_CLASS )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
NumberOfNamingAttributes =
lpNamingAttributes->dwNumberOfRequestEntries,
NamingAttributesBuffer =
lpNamingAttributes->lpRequestBuffer,
NamingAttributesBufferLength =
(WORD)lpNamingAttributes->dwLengthOfRequestData;
}
if ( lpMandatoryAttributes )
{
if ( lpMandatoryAttributes->dwBufferId != NDS_SIGNATURE ||
lpMandatoryAttributes->dwOperation != NDS_SCHEMA_DEFINE_CLASS )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
NumberOfMandatoryAttributes =
lpMandatoryAttributes->dwNumberOfRequestEntries,
MandatoryAttributesBuffer =
lpMandatoryAttributes->lpRequestBuffer,
MandatoryAttributesBufferLength =
(WORD)lpMandatoryAttributes->dwLengthOfRequestData;
}
if ( lpOptionalAttributes )
{
if ( lpOptionalAttributes->dwBufferId != NDS_SIGNATURE ||
lpOptionalAttributes->dwOperation != NDS_SCHEMA_DEFINE_CLASS )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
NumberOfOptionalAttributes =
lpOptionalAttributes->dwNumberOfRequestEntries,
OptionalAttributesBuffer =
lpOptionalAttributes->lpRequestBuffer,
OptionalAttributesBufferLength =
(WORD)lpOptionalAttributes->dwLengthOfRequestData;
}
RtlInitUnicodeString( &ClassName, szClassName );
ntstatus =
FragExWithWait(
lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_DEFINE_CLASS,
NdsReply,
NDS_BUFFER_SIZE,
&dwReplyLength,
"DDSDDrDrDrDrDr",
0, // Version
dwFlags,
&ClassName,
0, // ASN1 Id
NumberOfSuperClasses,
SuperClassesBuffer,
SuperClassesBufferLength,
NumberOfContainmentClasses,
ContainmentClassesBuffer,
ContainmentClassesBufferLength,
NumberOfNamingAttributes,
NamingAttributesBuffer,
NamingAttributesBufferLength,
NumberOfMandatoryAttributes,
MandatoryAttributesBuffer,
MandatoryAttributesBufferLength,
NumberOfOptionalAttributes,
OptionalAttributesBuffer,
OptionalAttributesBufferLength
);
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsDefineClass: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsDefineClass: The define class response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
DWORD
NwNdsDeleteAttrDef(
IN HANDLE hTree,
IN LPWSTR szAttributeName )
/*
NwNdsDeleteAttrDef()
This function is used to remove an attribute definition from the schema of
NDS tree hTree.
Arguments:
HANDLE hTree - A handle to the directory tree to be
manipulated. Handle is obtained by calling
NwNdsOpenObject.
LPWSTR szAttributeName - The name of the attribute
defintion to remove.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD nwstatus;
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_SUCCESS;
DWORD dwReplyLength;
BYTE NdsReply[NDS_BUFFER_SIZE];
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hTree;
UNICODE_STRING AttributeName;
if ( szAttributeName == NULL ||
lpNdsObject == NULL ||
lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
RtlInitUnicodeString( &AttributeName, szAttributeName );
ntstatus =
FragExWithWait(
lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_REMOVE_ATTR_DEF,
NdsReply,
NDS_BUFFER_SIZE,
&dwReplyLength,
"DS",
0, // Version
&AttributeName
);
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsDeleteAttrDef: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsDeleteAttrDef: The delete attribute response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
DWORD
NwNdsDeleteClassDef(
IN HANDLE hTree,
IN LPWSTR szClassName )
/*
NwNdsDeleteClassDef()
This function is used to remove a class definition from the schema of
NDS tree hTree.
Arguments:
HANDLE hTree - A handle to the directory tree to be
manipulated. Handle is obtained by calling
NwNdsOpenObject.
LPWSTR szClassName - The name of the class defintion to remove.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD nwstatus;
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_SUCCESS;
DWORD dwReplyLength;
BYTE NdsReply[NDS_BUFFER_SIZE];
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hTree;
UNICODE_STRING ClassName;
if ( szClassName == NULL ||
lpNdsObject == NULL ||
lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
RtlInitUnicodeString( &ClassName, szClassName );
ntstatus =
FragExWithWait(
lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_REMOVE_CLASS_DEF,
NdsReply,
NDS_BUFFER_SIZE,
&dwReplyLength,
"DS",
0, // Version
&ClassName
);
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsDeleteClassDef: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsDeleteClassDef: The delete class response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
VOID
NwNdsDeleteQueryNode(
IN LPQUERY_NODE lpQueryNode
)
/*
NwNdsDeleteQueryNode()
This function is used to free a tree node that was part of a query
used with the function NwNdsSearch.
Arguments:
LPQUERY_NODE lpQueryNode - A pointer to a particular node of
a query tree that defines a search. The tree is
created manually by the user through the function
NwNdsCreateQueryNode.
Returns:
Nothing
*/
{
(void) LocalFree( (HLOCAL) lpQueryNode );
lpQueryNode = NULL;
}
DWORD
NwNdsDeleteQueryTree(
IN LPQUERY_TREE lpQueryTree
)
/*
NwNdsDeleteQueryTree()
This function is used to free a tree that describes a query that was
used with the function NwNdsSearch.
Arguments:
LPQUERY_TREE lpQueryTree - A pointer to the root of a query
tree that defines a search.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD status;
switch( lpQueryTree->dwOperation )
{
case NDS_QUERY_OR :
case NDS_QUERY_AND :
if ( lpQueryTree->lpLVal == NULL || lpQueryTree->lpRVal == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsDeleteQueryTree was not passed a pointer to an L or R value.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
status = NwNdsDeleteQueryTree( lpQueryTree->lpLVal );
if ( status != NO_ERROR )
{
return status;
}
lpQueryTree->lpLVal = NULL;
status = NwNdsDeleteQueryTree( lpQueryTree->lpRVal );
if ( status != NO_ERROR )
{
return status;
}
lpQueryTree->lpRVal = NULL;
NwNdsDeleteQueryNode( lpQueryTree );
break;
case NDS_QUERY_NOT :
if ( lpQueryTree->lpLVal == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsCreateQueryNode was not passed a pointer to an L value.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
status = NwNdsDeleteQueryTree( lpQueryTree->lpLVal );
if ( status != NO_ERROR )
{
return status;
}
lpQueryTree->lpLVal = NULL;
NwNdsDeleteQueryNode( lpQueryTree );
break;
case NDS_QUERY_EQUAL :
case NDS_QUERY_GE :
case NDS_QUERY_LE :
case NDS_QUERY_APPROX :
case NDS_QUERY_PRESENT :
NwNdsDeleteQueryNode( lpQueryTree );
break;
default :
#if DBG
KdPrint(( "NDS32: NwNdsDeleteQueryTree was passed an unidentified operation - 0x%.8X.\n", lpQueryTree->dwOperation ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
return NO_ERROR;
}
DWORD
NwNdsFreeBuffer(
IN HANDLE hOperationData
)
/*
NwNdsFreeBuffer()
This function is used to free the buffer used to describe object
operations to a specific object in an NDS directory tree. The buffer must
be one created by NwNdsCreateBuffer, or returned by calling NwNdsReadObject,
NwNdsReadAttrDef, or NwNdsReadClassDef.
Arguments:
HANDLE hOperationData - Handle to buffer that is to be freed.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD status = NO_ERROR;
LPNDS_BUFFER lpNdsBuffer = (LPNDS_BUFFER) hOperationData;
if ( lpNdsBuffer == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsFreeBuffer was passed a NULL buffer pointer.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
if ( lpNdsBuffer->dwBufferId != NDS_SIGNATURE )
{
#if DBG
KdPrint(( "NDS32: NwNdsFreeBuffer was passed an unidentified buffer.\n" ));
ASSERT( FALSE );
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// If this buffer contains a pointer to an index buffer. Need to free
// the index buffer.
//
if ( lpNdsBuffer->lpIndexBuffer )
{
if ( lpNdsBuffer->dwOperation == NDS_SEARCH &&
lpNdsBuffer->dwNumberOfIndexEntries )
{
LPNDS_OBJECT_INFO lpObjectInfo = (LPNDS_OBJECT_INFO)
lpNdsBuffer->lpIndexBuffer;
DWORD iter;
for ( iter = 0; iter < lpNdsBuffer->dwNumberOfIndexEntries; iter++ )
{
(void) LocalFree( (HLOCAL) lpObjectInfo[iter].lpAttribute );
lpObjectInfo[iter].lpAttribute = NULL;
lpObjectInfo[iter].dwNumberOfAttributes = 0;
}
}
(void) LocalFree( (HLOCAL) lpNdsBuffer->lpIndexBuffer );
lpNdsBuffer->lpIndexBuffer = NULL;
}
//
// If this buffer contains a pointer to a reply buffer. Need to free
// the reply buffer.
//
if ( lpNdsBuffer->lpReplyBuffer )
{
(void) LocalFree( (HLOCAL) lpNdsBuffer->lpReplyBuffer );
lpNdsBuffer->lpReplyBuffer = NULL;
}
//
// If this buffer contains a pointer to a request buffer. Need to free
// the request buffer.
//
if ( lpNdsBuffer->lpRequestBuffer )
{
(void) LocalFree( (HLOCAL) lpNdsBuffer->lpRequestBuffer );
lpNdsBuffer->lpRequestBuffer = NULL;
}
//
// If this buffer contains a pointer to a syntax buffer. Need to free
// the syntax buffer.
//
if ( lpNdsBuffer->lpSyntaxBuffer )
{
(void) LocalFree( (HLOCAL) lpNdsBuffer->lpSyntaxBuffer );
lpNdsBuffer->lpSyntaxBuffer = NULL;
}
//
// Now free the handle buffer.
//
(void) LocalFree((HLOCAL) lpNdsBuffer);
return NO_ERROR;
}
DWORD
NwNdsGetAttrDefListFromBuffer(
IN HANDLE hOperationData,
OUT LPDWORD lpdwNumberOfEntries,
OUT LPDWORD lpdwInformationType,
OUT LPVOID * lppEntries )
/*
NwNdsGetAttrDefListFromBuffer()
This function is used to retrieve an array of attribute definition entries
for a schema that was read with a prior call to NwNdsReadAttrDef.
Arguments:
HANDLE hOperationData - Buffer containing the read
response from calling NwNdsReadAttrDef.
LPDWORD lpdwNumberOfEntries - The address of a DWORD to
receive the number of array elements pointed to by
lppEntries.
LPDWORD lpdwInformationType - The address of a DWORD to
receive a value that indicates the type of information
returned by the call to NwNdsReadAttrDef.
LPVOID * lppEntries - The address of a pointer to the beginning
of an array of attribute schema structures. Each
structure contains the details of each attribute
definition read from a given schema by calling
NwNdsReadAttrDef. The lppEntries value should be
cast to either a LPNDS_ATTR_DEF or LPNDS_NAME_ONLY
structure depending on the value returned in
lpdwInformationType.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
LPNDS_BUFFER lpNdsBuffer = (LPNDS_BUFFER) hOperationData;
//
// Check to see if the data handle is one for reading attribute definitions.
//
if ( lpNdsBuffer == NULL ||
lpNdsBuffer->dwBufferId != NDS_SIGNATURE ||
lpNdsBuffer->dwOperation != NDS_SCHEMA_READ_ATTR_DEF )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Check to see if NwNdsReadAttrDef has been called yet.
//
if ( lpNdsBuffer->lpReplyBuffer == NULL )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Check to see if the call to NwNdsReadAttrDef returned any attributes.
//
if ( lpNdsBuffer->dwNumberOfReplyEntries == 0 )
{
SetLastError( ERROR_NO_DATA );
return (DWORD) UNSUCCESSFUL;
}
//
// If TRUE, we need to walk raw response to set indexes to data within.
//
if ( lpNdsBuffer->lpIndexBuffer == NULL )
{
DWORD status;
if ( lpNdsBuffer->dwReplyInformationType == NDS_INFO_NAMES )
{
status = IndexReadNameReplyBuffer( lpNdsBuffer );
}
else
{
status = IndexReadAttrDefReplyBuffer( lpNdsBuffer );
}
if ( status )
{
SetLastError( status );
return (DWORD) UNSUCCESSFUL;
}
}
lpNdsBuffer->dwCurrentIndexEntry = 0;
*lpdwNumberOfEntries = lpNdsBuffer->dwNumberOfIndexEntries;
*lpdwInformationType = lpNdsBuffer->dwReplyInformationType;
*lppEntries = (LPVOID) lpNdsBuffer->lpIndexBuffer;
return NO_ERROR;
}
DWORD
NwNdsGetAttrListFromBuffer(
IN HANDLE hOperationData,
OUT LPDWORD lpdwNumberOfEntries,
OUT LPNDS_ATTR_INFO * lppEntries )
/*
NwNdsGetAttrListFromBuffer()
This function is used to retrieve an array of attribute entries for an
object that was read with a prior call to NwNdsReadObject.
Arguments:
HANDLE hOperationData - Buffer containing the read
response from calling NwNdsReadObject.
LPDWORD lpdwNumberOfEntries - The address of a DWORD to
receive the number of array elements pointed to by
lppEntries.
LPNDS_ATTR_INFO *
lppEntries - The address of a pointer to the beginning
of an array of NDS_ATTR_INFO structures. Each
structure contains the details of each attribute read
from a given object by calling NwNdsReadObject.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
LPNDS_BUFFER lpNdsBuffer = (LPNDS_BUFFER) hOperationData;
//
// Check to see if the data handle is one for reading attributes.
//
if ( lpNdsBuffer == NULL ||
lpNdsBuffer->dwBufferId != NDS_SIGNATURE ||
lpNdsBuffer->dwOperation != NDS_OBJECT_READ )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Check to see if NwNdsReadObject has been called yet.
//
if ( lpNdsBuffer->lpReplyBuffer == NULL )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Check to see if the call to NwNdsReadObject returned any attributes.
//
if ( lpNdsBuffer->dwNumberOfReplyEntries == 0 )
{
SetLastError( ERROR_NO_DATA );
return (DWORD) UNSUCCESSFUL;
}
//
// If TRUE, we need to walk raw response to set indexes to data within.
//
if ( lpNdsBuffer->lpIndexBuffer == NULL )
{
DWORD status;
if ( lpNdsBuffer->dwReplyInformationType == NDS_INFO_NAMES )
{
status = IndexReadNameReplyBuffer( lpNdsBuffer );
}
else
{
status = IndexReadObjectReplyBuffer( lpNdsBuffer );
}
if ( status )
{
SetLastError( status );
return (DWORD) UNSUCCESSFUL;
}
}
ASSERT( lpNdsBuffer->lpIndexBuffer != NULL );
lpNdsBuffer->dwCurrentIndexEntry = 0;
*lpdwNumberOfEntries = lpNdsBuffer->dwNumberOfIndexEntries;
*lppEntries = (LPNDS_ATTR_INFO) lpNdsBuffer->lpIndexBuffer;
return NO_ERROR;
}
DWORD
NwNdsGetClassDefListFromBuffer(
IN HANDLE hOperationData,
OUT LPDWORD lpdwNumberOfEntries,
OUT LPDWORD lpdwInformationType,
OUT LPVOID * lppEntries )
/*
NwNdsGetClassDefListFromBuffer()
This function is used to retrieve an array of class definition entries
for a schema that was read with a prior call to NwNdsReadClassDef.
Arguments:
HANDLE hOperationData - Buffer containing the read
response from calling NwNdsReadClassDef.
LPDWORD lpdwNumberOfEntries - The address of a DWORD to
receive the number of array elements pointed to by
lppEntries.
LPDWORD lpdwInformationType - The address of a DWORD to
receive a value that indicates the type of information
returned by the call to NwNdsReadClassDef.
LPVOID * lppEntries - The address of a pointer to the beginning
of an array of schema class structures. Each
structure contains the details of each class
definition read from a given schema by calling
NwNdsReadClassDef. The lppEntries value should be
cast to either a LPNDS_CLASS_DEF or LPNDS_DEF_NAME_ONLY
structure depending on the value returned in
lpdwInformationType.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
LPNDS_BUFFER lpNdsBuffer = (LPNDS_BUFFER) hOperationData;
//
// Check to see if the data handle is one for reading class definitions.
//
if ( lpNdsBuffer == NULL ||
lpNdsBuffer->dwBufferId != NDS_SIGNATURE ||
lpNdsBuffer->dwOperation != NDS_SCHEMA_READ_CLASS_DEF )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Check to see if NwNdsReadClassDef has been called yet.
//
if ( lpNdsBuffer->lpReplyBuffer == NULL )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Check to see if the call to NwNdsReadClassDef returned any classes.
//
if ( lpNdsBuffer->dwNumberOfReplyEntries == 0 )
{
SetLastError( ERROR_NO_DATA );
return (DWORD) UNSUCCESSFUL;
}
//
// If TRUE, we need to walk raw response to set indexes to data within.
//
if ( lpNdsBuffer->lpIndexBuffer == NULL )
{
DWORD status;
if ( lpNdsBuffer->dwReplyInformationType == NDS_INFO_NAMES )
{
status = IndexReadNameReplyBuffer( lpNdsBuffer );
}
else
{
status = IndexReadClassDefReplyBuffer( lpNdsBuffer );
}
if ( status )
{
SetLastError( status );
return (DWORD) UNSUCCESSFUL;
}
}
ASSERT( lpNdsBuffer->lpIndexBuffer != NULL );
lpNdsBuffer->dwCurrentIndexEntry = 0;
*lpdwNumberOfEntries = lpNdsBuffer->dwNumberOfIndexEntries;
*lpdwInformationType = lpNdsBuffer->dwReplyInformationType;
*lppEntries = (LPVOID) lpNdsBuffer->lpIndexBuffer;
return NO_ERROR;
}
DWORD
NwNdsGetEffectiveRights(
IN HANDLE hObject,
IN LPWSTR szSubjectName,
IN LPWSTR szAttributeName,
OUT LPDWORD lpdwRights )
/*
NwNdsGetEffectiveRights()
This function is used to determine the effective rights of a particular
subject on a particular object in the NDS tree. The user needs to have
appropriate priveleges to make the determination.
Arguments:
HANDLE hObject - A handle to the object in the directory
tree to determine effective rights on. Handle is
obtained by calling NwNdsOpenObject.
LPWSTR szSubjectName - The distinguished name of user whose
rights we're interested in determining.
LPWSTR szAttributeName - Regular attribute name (i.e.
L"Surname" , L"CN" ) for reading a particular
attribute right, or L"[All Attribute Rights]" and
L"[Entry Rights]" can be used to determine the default
attribute rights and object rights respectively.
LPDWORD lpdwRights - A pointer to a DWORD to receive the
results. If the call is successful, lpdwRights will
contain a mask representing the subject's rights:
Attribute rights - NDS_RIGHT_COMPARE_ATTR,
NDS_RIGHT_READ_ATTR, NDS_RIGHT_WRITE_ATTR,
NDS_RIGHT_ADD_SELF_ATTR, and
NDS_RIGHT_SUPERVISE_ATTR.
Object rights - NDS_RIGHT_BROWSE_OBJECT,
NDS_RIGHT_CREATE_OBJECT, NDS_RIGHT_DELETE_OBJECT,
NDS_RIGHT_RENAME_OBJECT, and
NDS_RIGHT_SUPERVISE_OBJECT.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD nwstatus;
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_SUCCESS;
DWORD dwReplyLength;
BYTE NdsReply[NDS_BUFFER_SIZE];
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hObject;
UNICODE_STRING SubjectName;
UNICODE_STRING AttributeName;
if ( szAttributeName == NULL ||
szSubjectName == NULL ||
lpNdsObject == NULL ||
lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
RtlInitUnicodeString( &SubjectName, szSubjectName );
RtlInitUnicodeString( &AttributeName, szAttributeName );
ntstatus =
FragExWithWait(
lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_GET_EFFECTIVE_RIGHTS,
NdsReply,
NDS_BUFFER_SIZE,
&dwReplyLength,
"DDSS",
0, // Version
lpNdsObject->ObjectId,
&SubjectName,
&AttributeName
);
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsGetEffectiveRights: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsGetEffectiveRights: The status code response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
if ( nwstatus )
{
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"G_D",
1 * sizeof(DWORD),
lpdwRights );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsGetEffectiveRights: The effective rights response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
DWORD
NwNdsGetObjectListFromBuffer(
IN HANDLE hOperationData,
OUT LPDWORD lpdwNumberOfEntries,
OUT LPDWORD lpdwAttrInformationType OPTIONAL,
OUT LPNDS_OBJECT_INFO * lppEntries )
/*
NwNdsGetObjectListFromBuffer()
This function is used to retrieve an array of object entries for
objects that were read with a prior call to either
NwNdsListSubObjects or NwNdsSearch.
Arguments:
HANDLE hOperationData - Buffer containing the read
response from calling NwNdsListSubObjects, or a
buffer containing the search results from a call
to NwNdsSearch.
LPDWORD lpdwNumberOfEntries - The address of a DWORD to
receive the number of array elements pointed to by
lppEntries.
LPDWORD lpdwAttrInformationType - The address of a DWORD to
receive a value that indicates the type of attribute
information returned by the call to NwNdsSearch.
This attribute information type determines which
buffer structure (LPNDS_ATTR_INFO or LPNDS_NAME_ONLY)
should be used for the lpAttribute field found in
each NDS_OBJECT_INFO structure below.
- or -
NULL to indicate that the callee is not interested,
especially when the object list is that from a call
to NwNdsListSubObjects.
LPNDS_OBJECT_INFO *
lppEntries - The address of a pointer to the beginning
of an array of NDS_OBJECT_INFO structures. Each
structure contains the details of each object returned
from a call to NwNdsListSubObjects or NwNdsSearch.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
LPNDS_BUFFER lpNdsBuffer = (LPNDS_BUFFER) hOperationData;
*lpdwNumberOfEntries = 0;
*lppEntries = NULL;
//
// Check to see if the data handle is one for listing subordinates or
// for searching.
//
if ( lpNdsBuffer == NULL ||
lpNdsBuffer->dwBufferId != NDS_SIGNATURE ||
( lpNdsBuffer->dwOperation != NDS_OBJECT_LIST_SUBORDINATES &&
lpNdsBuffer->dwOperation != NDS_SEARCH ) )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Check to see if the call to NwNdsListSubObjects returned any objects.
//
if ( lpNdsBuffer->dwOperation == NDS_OBJECT_LIST_SUBORDINATES &&
lpNdsBuffer->dwNumberOfIndexEntries == 0 )
{
SetLastError( ERROR_NO_DATA );
return (DWORD) UNSUCCESSFUL;
}
//
// Check to see if the call to NwNdsSearch returned any objects.
//
if ( lpNdsBuffer->dwOperation == NDS_SEARCH &&
lpNdsBuffer->dwNumberOfReplyEntries == 0 )
{
SetLastError( ERROR_NO_DATA );
return (DWORD) UNSUCCESSFUL;
}
//
// If TRUE, we need to walk raw response to set indexes to data within.
//
if ( lpNdsBuffer->dwOperation == NDS_SEARCH &&
lpNdsBuffer->lpIndexBuffer == NULL )
{
DWORD status;
status = IndexSearchObjectReplyBuffer( lpNdsBuffer );
if ( status )
{
SetLastError( status );
return (DWORD) UNSUCCESSFUL;
}
}
ASSERT( lpNdsBuffer->lpIndexBuffer != NULL );
lpNdsBuffer->dwCurrentIndexEntry = 0;
*lpdwNumberOfEntries = lpNdsBuffer->dwNumberOfIndexEntries;
*lppEntries = (LPNDS_OBJECT_INFO) lpNdsBuffer->lpIndexBuffer;
if ( lpdwAttrInformationType )
{
*lpdwAttrInformationType = lpNdsBuffer->dwReplyInformationType;
}
return NO_ERROR;
}
DWORD
NwNdsGetSyntaxID(
IN HANDLE hTree,
IN LPWSTR szlpAttributeName,
OUT LPDWORD lpdwSyntaxID )
/*
NwNdsGetObjListFromBuffer()
This function is used to retrieve the Syntax ID of a given attribute name.
Arguments:
HANDLE hTree - A handle to the directory tree to be
manipulated. Handle is obtained by calling
NwNdsOpenObject.
LPWSTR szlpAttributeName - The attribute name whose Syntax ID
is requested.
LPDWORD lpdwSyntaxID - The address of a DWORD to receive the
SyntaxID.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD nwstatus;
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_SUCCESS;
DWORD dwReplyLength;
BYTE NdsReply[NDS_BUFFER_SIZE];
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hTree;
UNICODE_STRING AttributeName;
DWORD dwNumEntries;
DWORD dwStringLen;
LPBYTE lpByte;
DWORD LengthInBytes;
LPBYTE lpTempEntry = NULL;
if ( lpNdsObject == NULL ||
szlpAttributeName == NULL ||
lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
RtlInitUnicodeString( &AttributeName, szlpAttributeName );
// allocate enough extra space for the padding PrepareReadEntry will do
lpTempEntry = LocalAlloc( LPTR, AttributeName.Length + (2*sizeof(DWORD)) );
if ( ! lpTempEntry )
{
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
PrepareReadEntry( lpTempEntry,
AttributeName,
&LengthInBytes );
ntstatus = FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_READ_ATTR_DEF,
NdsReply,
NDS_BUFFER_SIZE,
&dwReplyLength,
"DDDDDr",
0, // Version
NDS_NO_MORE_ITERATIONS, // Initial iteration
NDS_INFO_NAMES_DEFS,
(DWORD) FALSE, // All attributes indicator
1, // Number of attributes
lpTempEntry,
LengthInBytes);
(void) LocalFree((HLOCAL) lpTempEntry );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsGetSyntaxID: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsGetSyntaxID: The get syntax id response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
if ( nwstatus )
{
#if DBG
KdPrint(( "NDS32: NwNdsGetSyntaxID: NetWare error 0x%.8X reading %ws.\n", nwstatus, szlpAttributeName ));
#endif
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"G_D",
3 * sizeof(DWORD),
&dwNumEntries );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsGetSyntaxID: The attribute read response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ASSERT( dwNumEntries == 1 );
//
// Set lpByte to the point in the reply buffer that has the attribute
// name length.
//
lpByte = NdsReply + ( 4 * sizeof(DWORD) );
//
// Get the attribute name length and move lpByte to beginning of
// attribute name
//
dwStringLen = * (LPDWORD) lpByte;
lpByte += sizeof(DWORD);
//
// Move lpByte past the attribute name so that it points to the
// attribute flags value
//
lpByte += ROUND_UP_COUNT( dwStringLen,
ALIGN_DWORD);
//
// Move lpByte past the attribute flags value so that it now points to
// the attribute syntax id value
//
lpByte += sizeof(DWORD);
*lpdwSyntaxID = * (LPDWORD) lpByte;
return NO_ERROR;
}
DWORD
NwNdsListSubObjects(
IN HANDLE hParentObject,
IN DWORD dwEntriesRequested,
OUT LPDWORD lpdwEntriesReturned,
IN LPNDS_FILTER_LIST lpFilters OPTIONAL,
OUT HANDLE * lphOperationData )
/*
NwNdsListSubObjects()
This function is used to enumerate the subordinate objects for a particular
parent object. A filter can be passed in to restrict enumeration to a
a specific class type or list of class types.
Arguments:
HANDLE hParentObject - A handle to the object in the directory
tree whose subordinate objects (if any) will be
enumerated.
DWORD dwEntriesRequested - The number of subordinate objects
to list. A subsequent call to NwNdsListSubObjects will
continue enumeration following the last item returned.
LPDWORD lpdwEntriesReturned - A pointer to a DWORD that will
contain the actual number of subobjects enumerated in
the call.
LPNDS_FILTER_LIST lpFilters - The caller can specify the object class
names for the kinds of objects that they would like
to enumerate. For example if just User and Group
object classes should be enumerated, then a filter
for class names NDS_CLASS_USER and NDS_CLASS_GROUP
should be pass in.
- or -
NULL to indicate that all objects should be returned
(no filter).
HANDLE * lphOperationData - Address of a HANDLE handle to
receive created buffer that contains the list of
subordinate objects read from the object
hParentObject. This handle is manipulated by the
following functions:
NwNdsGetObjListFromBuffer and NwNdsFreeBuffer.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD status = NO_ERROR;
LPNDS_BUFFER lpNdsBuffer = NULL;
LPNDS_OBJECT_PRIV lpNdsParentObject = (LPNDS_OBJECT_PRIV) hParentObject;
LPBYTE FixedPortion = NULL;
LPWSTR EndOfVariableData = NULL;
BOOL FitInBuffer = TRUE;
//
// Test the parameters.
//
if ( lpNdsParentObject == NULL ||
lpNdsParentObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
if ( lpNdsParentObject->ResumeId == NDS_NO_MORE_ITERATIONS )
{
if ( lpNdsParentObject->NdsRawDataBuffer )
{
(void) LocalFree( (HLOCAL) lpNdsParentObject->NdsRawDataBuffer );
lpNdsParentObject->NdsRawDataBuffer = 0;
lpNdsParentObject->NdsRawDataSize = 0;
lpNdsParentObject->NdsRawDataId = INITIAL_ITERATION;
lpNdsParentObject->NdsRawDataCount = 0;
}
//
// Reached the end of enumeration.
//
return WN_NO_MORE_ENTRIES;
}
//
// Allocate a results buffer
//
status = NwNdsCreateBuffer( NDS_OBJECT_LIST_SUBORDINATES,
(HANDLE *) &lpNdsBuffer );
if ( status )
{
return status;
}
FixedPortion = lpNdsBuffer->lpIndexBuffer;
EndOfVariableData = (LPWSTR) ((DWORD_PTR) FixedPortion +
ROUND_DOWN_COUNT(
lpNdsBuffer->dwIndexAvailableBytes,
ALIGN_DWORD ) );
*lpdwEntriesReturned = 0;
*lphOperationData = NULL;
while ( FitInBuffer &&
dwEntriesRequested > *lpdwEntriesReturned &&
status == NO_ERROR )
{
if ( lpNdsParentObject->ResumeId == 0 )
{
//
// Get the first subtree entry.
//
status = GetFirstNdsSubTreeEntry( lpNdsParentObject,
lpNdsBuffer->dwRequestAvailableBytes );
}
//
// Either ResumeId contains the first entry we just got from
// GetFirstNdsSubTreeEntry or it contains the next directory
// entry to return.
//
if (status == NO_ERROR && lpNdsParentObject->ResumeId != 0)
{
WORD tempStrLen;
LPWSTR newPathStr = NULL;
LPWSTR tempStr = NULL;
LPWSTR ClassName;
LPWSTR ObjectName;
DWORD ClassNameLen;
DWORD ObjectNameLen;
DWORD EntryId;
DWORD SubordinateCount;
DWORD ModificationTime;
BOOL fWriteThisObject = FALSE;
//
// Get current subtree data from lpNdsParentObject
//
GetSubTreeData( lpNdsParentObject->ResumeId,
&EntryId,
&SubordinateCount,
&ModificationTime,
&ClassNameLen,
&ClassName,
&ObjectNameLen,
&ObjectName );
if ( lpFilters )
{
DWORD iter;
for ( iter = 0; iter < lpFilters->dwNumberOfFilters; iter++ )
{
if (!wcscmp(lpFilters->Filters[iter].szObjectClass, ClassName))
fWriteThisObject = TRUE;
}
}
else
{
fWriteThisObject = TRUE;
}
if ( fWriteThisObject )
{
//
// Need to build a string with the new NDS UNC path
// for subtree object
//
newPathStr = (PVOID) LocalAlloc( LPTR,
( wcslen(ObjectName) +
wcslen(lpNdsParentObject->szContainerName) +
3 ) * sizeof(WCHAR) );
if ( newPathStr == NULL )
{
(void) NwNdsFreeBuffer( (HANDLE) lpNdsBuffer );
#if DBG
KdPrint(("NDS32: NwNdsListSubObjects LocalAlloc Failed 0x%.8X\n", GetLastError()));
#endif
return ERROR_NOT_ENOUGH_MEMORY;
}
tempStrLen = ParseNdsUncPath( (LPWSTR *) &tempStr,
lpNdsParentObject->szContainerName,
PARSE_NDS_GET_TREE_NAME );
tempStrLen /= sizeof(WCHAR);
if ( tempStrLen > 0 )
{
wcscpy( newPathStr, L"\\\\" );
wcsncat( newPathStr, tempStr, tempStrLen );
wcscat( newPathStr, L"\\" );
wcscat( newPathStr, ObjectName );
_wcsupr( newPathStr );
}
tempStrLen = ParseNdsUncPath( (LPWSTR *) &tempStr,
lpNdsParentObject->szContainerName,
PARSE_NDS_GET_PATH_NAME );
tempStrLen /= sizeof(WCHAR);
if ( tempStrLen > 0 )
{
wcscat( newPathStr, L"." );
wcsncat( newPathStr, tempStr, tempStrLen );
}
//
// Pack subtree name into output buffer.
//
status = WriteObjectToBuffer( &FixedPortion,
&EndOfVariableData,
newPathStr,
ObjectName,
ClassName,
EntryId,
ModificationTime,
SubordinateCount,
0, // No attribute
NULL ); // infos here
if ( status == NO_ERROR )
{
//
// Note that we've returned the current entry.
//
(*lpdwEntriesReturned)++;
(lpNdsBuffer->dwNumberOfIndexEntries)++;
}
if ( newPathStr )
(void) LocalFree( (HLOCAL) newPathStr );
}
if (status == WN_MORE_DATA)
{
//
// Could not write current entry into output buffer.
//
if (*lpdwEntriesReturned)
{
//
// Still return success because we got at least one.
//
status = NO_ERROR;
}
FitInBuffer = FALSE;
}
else if (status == NO_ERROR)
{
//
// Get next directory entry.
//
status = GetNextNdsSubTreeEntry( lpNdsParentObject );
}
} // end of if data to process
if (status == WN_NO_MORE_ENTRIES)
{
lpNdsParentObject->ResumeId = NDS_NO_MORE_ITERATIONS;
}
} //end of while loop
//
// User asked for more than there are entries. We just say that
// all is well.
//
// This is incompliance with the wierd provider API definition where
// if user gets NO_ERROR, and EntriesRequested > *EntriesRead, and
// at least one entry fit into output buffer, there's no telling if
// the buffer was too small for more entries or there are no more
// entries. The user has to call this API again and get WN_NO_MORE_ENTRIES
// before knowing that the last call had actually reached the end of list.
//
if ( *lpdwEntriesReturned && status == WN_NO_MORE_ENTRIES )
{
status = NO_ERROR;
}
if ( *lpdwEntriesReturned )
{
*lphOperationData = lpNdsBuffer;
}
if ( *lpdwEntriesReturned == 0 )
{
(void) NwNdsFreeBuffer( (HANDLE) lpNdsBuffer );
lpNdsBuffer = NULL;
}
if ( lpNdsParentObject->NdsRawDataBuffer &&
lpNdsParentObject->ResumeId == NDS_NO_MORE_ITERATIONS )
{
(void) LocalFree( (HLOCAL) lpNdsParentObject->NdsRawDataBuffer );
lpNdsParentObject->NdsRawDataBuffer = 0;
lpNdsParentObject->NdsRawDataSize = 0;
lpNdsParentObject->NdsRawDataId = INITIAL_ITERATION;
lpNdsParentObject->NdsRawDataCount = 0;
}
return status;
}
DWORD
NwNdsModifyObject(
IN HANDLE hObject,
IN HANDLE hOperationData )
/*
NwNdsModifyObject()
This function is used to modify a leaf object in an NDS directory tree.
Modifying a leaf object means: changing, adding, removing, and clearing of
specified attributes for a given object.
Arguments:
HANDLE hObject - A handle to the object in the directory
tree to be manipulated. Handle is obtained by calling
NwNdsOpenObject.
HANDLE hOperationData - A handle to data containing a
list of attribute changes to be applied to the object.
This buffer is manipulated by the following functions:
NwNdsCreateBuffer (NDS_OBJECT_MODIFY),
NwNdsPutInBuffer, and NwNdsFreeBuffer.
Returns:
NO_ERROR
ERROR_INVALID_PARAMETER
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD nwstatus;
NTSTATUS ntstatus = STATUS_SUCCESS;
DWORD dwReplyLength;
BYTE NdsReply[NDS_BUFFER_SIZE];
LPNDS_BUFFER lpNdsBuffer = (LPNDS_BUFFER) hOperationData;
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hObject;
if ( lpNdsBuffer == NULL ||
lpNdsObject == NULL ||
lpNdsBuffer->dwOperation != NDS_OBJECT_MODIFY ||
lpNdsBuffer->dwBufferId != NDS_SIGNATURE ||
lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
ntstatus =
FragExWithWait(
lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_MODIFY_OBJECT,
NdsReply,
NDS_BUFFER_SIZE,
&dwReplyLength,
"DDDDr",
0, // Version
0, // Flags
lpNdsObject->ObjectId, // The id of the object
lpNdsBuffer->dwNumberOfRequestEntries,
lpNdsBuffer->lpRequestBuffer, // Object attribute changes
(WORD)lpNdsBuffer->dwLengthOfRequestData // Length of data
);
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsModifyObject: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsModifyObject: The modify object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
DWORD
NwNdsMoveObject(
IN HANDLE hObject,
IN LPWSTR szDestObjectParentDN )
/*
NwNdsMoveObject()
This function is used to move a leaf object in an NDS directory tree
from one container to another.
Arguments:
HANDLE hObject - A handle to the object in the directory
tree to be moved. Handle is obtained by calling
NwNdsOpenObject.
LPWSTR szDestObjectParentDN - The DN of the object's new
parent.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD nwstatus;
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_SUCCESS;
DWORD dwReplyLength;
BYTE NdsReply[NDS_BUFFER_SIZE];
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hObject;
LPNDS_OBJECT_PRIV lpNdsDestParentObject = NULL;
WCHAR szServerDN[NDS_MAX_NAME_CHARS];
UNICODE_STRING ObjectName;
UNICODE_STRING ServerDN;
DWORD dwDestParentObjectId;
if ( szDestObjectParentDN == NULL ||
lpNdsObject == NULL ||
lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
RtlZeroMemory( &szServerDN, sizeof( szServerDN ) );
status = NwNdsGetServerDN( lpNdsObject, szServerDN );
if ( status )
{
return status;
}
status = NwNdsOpenObject( szDestObjectParentDN,
NULL,
NULL,
(HANDLE *) &lpNdsDestParentObject,
NULL,
NULL,
NULL,
NULL,
NULL );
if ( status )
{
return status;
}
dwDestParentObjectId = lpNdsDestParentObject->ObjectId;
(void) NwNdsCloseObject( (HANDLE) lpNdsDestParentObject );
RtlInitUnicodeString( &ObjectName, lpNdsObject->szRelativeName );
RtlInitUnicodeString( &ServerDN, szServerDN );
ntstatus =
FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_BEGIN_MOVE_OBJECT,
NdsReply,
NDS_BUFFER_SIZE,
&dwReplyLength,
"DDDSS",
0, // Version
0x00000000, // Some value
dwDestParentObjectId,
&ObjectName,
&ServerDN
);
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsMoveObject: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsMoveObject: The status code response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
if ( nwstatus )
{
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
ntstatus =
FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_FINISH_MOVE_OBJECT,
NdsReply,
NDS_BUFFER_SIZE,
&dwReplyLength,
"DDDDSS",
0, // Version
0x00000001, // Some value
lpNdsObject->ObjectId,
dwDestParentObjectId,
&ObjectName,
&ServerDN
);
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsMoveObject: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsMoveObject: The status code response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
if ( nwstatus )
{
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
return nwstatus;
}
DWORD
NwNdsOpenObject(
IN LPWSTR szObjectDN,
IN LPWSTR UserName OPTIONAL,
IN LPWSTR Password OPTIONAL,
OUT HANDLE * lphObject,
OUT LPWSTR szObjectName OPTIONAL,
OUT LPWSTR szObjectFullName OPTIONAL,
OUT LPWSTR szObjectClassName OPTIONAL,
OUT LPDWORD lpdwModificationTime OPTIONAL,
OUT LPDWORD lpdwSubordinateCount OPTIONAL )
/*
NwNdsOpenObject()
Arguments:
LPWSTR szObjectDN - The distinguished name of the object
that we want resolved into an object handle.
LPWSTR UserName - The name of the user account to create
connection to object with.
- OR -
NULL to use the base credentials of the callee's LUID.
LPWSTR Password - The password of the user account to create
connection to object with. If password is blank, callee
should pass "".
- OR -
NULL to use the base credentials of the callee's LUID.
HANDLE * lphObject - The address of a NDS_OBJECT_HANDLE
to receive the handle of the object specified by
szObjectDN.
Optional arguments: ( Callee can pass NULL in for these parameters to
indicate ignore )
LPWSTR szObjectName - A LPWSTR buffer to receive
the object's NDS name, or NULL if not
interested. The buffer for this string must be
provided by the user. Buffer should be at least
NDS_MAX_NAME_SIZE
LPWSTR szObjectFullName - A LPWSTR buffer to receive
the object's full NDS name (DN), or NULL if not
interested. The buffer for this string must be
provided by the user. Buffer should be at least
NDS_MAX_NAME_SIZE
LPWSTR szObjectClassName - A LPWSTR buffer to receive
the class name of the object opened, or NULL if not
interested. The buffer for this string must be
provided by the user. Buffer should be at least
NDS_MAX_NAME_SIZE.
LPDWORD lpdwModificationTime - The address of a DWORD to
receive the last date/time the object was modified.
LPDWORD lpdwSubordinateCount - The address of a DWORD to
receive the number of subordinate objects that may
be found under szObjectDN, if it is a container object.
Or, NULL in not interested.
If szObjectDN is not a container, then the value is set
to zero. Although a value of zero does not imply
that object is not a container, it could just be empty.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_SUCCESS;
WCHAR szServerName[NW_MAX_SERVER_LEN];
UNICODE_STRING ServerName;
UNICODE_STRING ObjectName;
LPNDS_OBJECT_PRIV lpNdsObject = NULL;
#ifdef WIN95
LPWSTR pszObjectName = NULL;
LPWSTR szWin95ClassName = NULL;
#endif
if ( szObjectDN == NULL )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
lpNdsObject = (LPNDS_OBJECT_PRIV) LocalAlloc( LPTR,
sizeof(NDS_OBJECT_PRIV) );
if (lpNdsObject == NULL) {
#if DBG
KdPrint(("NDS32: NwNdsOpenObject LocalAlloc Failed 0x%.8X\n", GetLastError()));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
ServerName.Length = 0;
ServerName.MaximumLength = sizeof(szServerName);
ServerName.Buffer = szServerName;
ObjectName.Buffer = NULL;
ObjectName.MaximumLength = (wcslen( szObjectDN ) + 1) * sizeof(WCHAR);
ObjectName.Length = ParseNdsUncPath( (LPWSTR *) &ObjectName.Buffer,
szObjectDN,
PARSE_NDS_GET_TREE_NAME );
if ( ObjectName.Length == 0 || ObjectName.Buffer == NULL )
{
SetLastError( ERROR_PATH_NOT_FOUND );
goto ErrorExit;
}
//
// Open a NDS tree connection handle to \\treename
//
if ( UserName && Password )
{
UNICODE_STRING usUserName;
UNICODE_STRING usPassword;
DWORD dwHandleType;
RtlInitUnicodeString( &usUserName, UserName );
RtlInitUnicodeString( &usPassword, Password );
ntstatus = NwOpenHandleWithSupplementalCredentials(
&ObjectName,
&usUserName,
&usPassword,
&dwHandleType,
&lpNdsObject->NdsTree );
if ( ntstatus == STATUS_SUCCESS &&
dwHandleType != HANDLE_TYPE_NDS_TREE )
{
SetLastError( ERROR_PATH_NOT_FOUND );
goto ErrorExit;
}
}
else if ( !UserName && !Password )
{
ntstatus = NwNdsOpenTreeHandle( &ObjectName, &lpNdsObject->NdsTree );
}
else
{
SetLastError( ERROR_INVALID_PARAMETER );
goto ErrorExit;
}
if ( ntstatus != STATUS_SUCCESS )
{
SetLastError( RtlNtStatusToDosError( ntstatus ) );
goto ErrorExit;
}
ObjectName.Length /= sizeof(WCHAR);
wcscpy( lpNdsObject->szContainerName, L"\\\\" );
wcsncat( lpNdsObject->szContainerName, ObjectName.Buffer, ObjectName.Length );
wcscat( lpNdsObject->szContainerName, L"\\" );
_wcsupr( lpNdsObject->szContainerName );
//
// Get the path to the container to open.
//
ObjectName.Length = ParseNdsUncPath( (LPWSTR *) &ObjectName.Buffer,
szObjectDN,
PARSE_NDS_GET_PATH_NAME );
if ( ObjectName.Length == 0 )
{
UNICODE_STRING Root;
RtlInitUnicodeString(&Root, L"[Root]");
//
// Resolve the path to get a NDS object id of [Root].
//
#ifndef WIN95
ntstatus = NwNdsResolveName( lpNdsObject->NdsTree,
&Root,
&lpNdsObject->ObjectId,
&ServerName,
NULL,
0 );
#else
ntstatus = NwNdsResolveNameWin95( lpNdsObject->NdsTree,
&Root,
&lpNdsObject->ObjectId,
&lpNdsObject->NdsTree,
NULL,
0 );
#endif
if ( ntstatus != STATUS_SUCCESS )
{
DWORD status;
status = RtlNtStatusToDosError( ntstatus );
if ( status == ERROR_NOT_CONNECTED )
SetLastError( ERROR_PATH_NOT_FOUND );
else
SetLastError( status );
goto ErrorExit;
}
}
else
{
//
// Resolve the path to get a NDS object id.
//
#ifndef WIN95
ntstatus = NwNdsResolveName( lpNdsObject->NdsTree,
&ObjectName,
&lpNdsObject->ObjectId,
&ServerName,
NULL,
0 );
#else
ntstatus = NwNdsResolveNameWin95( lpNdsObject->NdsTree,
&ObjectName,
&lpNdsObject->ObjectId,
&lpNdsObject->NdsTree,
NULL,
0 );
#endif
if ( ntstatus != STATUS_SUCCESS )
{
DWORD status;
status = RtlNtStatusToDosError( ntstatus );
if ( status == ERROR_NOT_CONNECTED )
SetLastError( ERROR_PATH_NOT_FOUND );
else
SetLastError( status );
goto ErrorExit;
}
}
#ifndef WIN95
if ( ServerName.Length )
{
DWORD dwHandleType;
//
// NwNdsResolveName succeeded, but we were referred to
// another server, though lpNdsObject->ObjectId is still valid.
//
if ( lpNdsObject->NdsTree )
CloseHandle( lpNdsObject->NdsTree );
lpNdsObject->NdsTree = 0;
//
// Open a NDS generic connection handle to \\ServerName
//
ntstatus = NwNdsOpenGenericHandle( &ServerName,
&dwHandleType,
&lpNdsObject->NdsTree );
if ( ntstatus != STATUS_SUCCESS )
{
SetLastError( RtlNtStatusToDosError( ntstatus ) );
goto ErrorExit;
}
}
{
PBYTE RawResponse = NULL;
PNDS_RESPONSE_GET_OBJECT_INFO psGetInfo;
PBYTE pbRawGetInfo;
LPWSTR szClassName;
DWORD dwStrLen;
RawResponse = LocalAlloc( LPTR, TWO_KB );
if ( ! RawResponse )
{
SetLastError(ERROR_NOT_ENOUGH_MEMORY);
goto ErrorExit;
}
ntstatus = NwNdsReadObjectInfo( lpNdsObject->NdsTree,
lpNdsObject->ObjectId,
RawResponse,
TWO_KB );
if ( ntstatus != STATUS_SUCCESS )
{
SetLastError( RtlNtStatusToDosError( ntstatus ) );
goto ErrorExit;
}
psGetInfo = ( PNDS_RESPONSE_GET_OBJECT_INFO ) RawResponse;
if ( lpdwModificationTime != NULL )
{
*lpdwModificationTime = psGetInfo->ModificationTime;
}
if ( lpdwSubordinateCount != NULL )
{
*lpdwSubordinateCount = psGetInfo->SubordinateCount;
}
//
// Dig out the two unicode strings for class name and object name.
//
pbRawGetInfo = RawResponse;
pbRawGetInfo += sizeof (NDS_RESPONSE_GET_OBJECT_INFO);
dwStrLen = * (LPDWORD) pbRawGetInfo;
pbRawGetInfo += sizeof(DWORD);
szClassName = (LPWSTR) pbRawGetInfo;
if ( szObjectClassName != NULL )
{
wcscpy( szObjectClassName, szClassName );
}
pbRawGetInfo += ROUNDUP4( dwStrLen );
dwStrLen = * ( DWORD * ) pbRawGetInfo;
pbRawGetInfo += sizeof(DWORD);
//
// Clean up the object's relative name ...
//
if ( wcscmp( szClassName, NDS_CLASS_TOP ) )
{
LPWSTR szTempStr = (LPWSTR) pbRawGetInfo;
while ( *szTempStr != L'=' )
{
szTempStr++;
}
szTempStr++;
wcscpy( lpNdsObject->szRelativeName, szTempStr );
szTempStr = lpNdsObject->szRelativeName;
while ( *szTempStr && *szTempStr != L'.' )
{
szTempStr++;
}
*szTempStr = L'\0';
}
else
{
wcscpy( lpNdsObject->szRelativeName, (LPWSTR) pbRawGetInfo );
}
if ( szObjectName != NULL )
{
wcscpy( szObjectName, lpNdsObject->szRelativeName );
}
if ( szObjectFullName != NULL )
{
if ( wcscmp( szClassName, NDS_CLASS_TOP ) )
{
wcscpy( szObjectFullName, lpNdsObject->szContainerName );
wcscat( szObjectFullName, (LPWSTR) pbRawGetInfo );
}
else
{
wcscpy( szObjectFullName,
lpNdsObject->szContainerName );
szObjectFullName[wcslen( szObjectFullName ) - 1] = L'\0';
}
}
//
// If the object is at a level below the root of the tree, append
// it's full DN to handle Name.
//
if ( wcscmp( szClassName, NDS_CLASS_TOP ) )
{
wcscat(lpNdsObject->szContainerName, (LPWSTR) pbRawGetInfo);
}
if ( RawResponse )
LocalFree( RawResponse );
}
lpNdsObject->Signature = NDS_SIGNATURE;
//
// Initialize ListSubObject/Search structure values.
//
// lpNdsObject->ResumeId = 0; // Start of enumeration
//
// lpNdsObject->NdsRawDataBuffer = 0;
// lpNdsObject->NdsRawDataSize = 0;
// lpNdsObject->NdsRawDataId = 0; // These are initialized by
// lpNdsObject->NdsRawDataCount = 0; // LPTR
//
// Return the newly created object handle.
//
*lphObject = (HANDLE) lpNdsObject;
return NO_ERROR;
#else
{
DS_OBJ_INFO dsobj;
DWORD dwStrLen;
NW_STATUS nwstatus;
memset(&dsobj, 0, sizeof(DS_OBJ_INFO));
nwstatus = NDSGetObjectInfoWithId(lpNdsObject->NdsTree,
lpNdsObject->ObjectId,
&dsobj );
ntstatus = MapNwToNtStatus(nwstatus);
if ( ntstatus != STATUS_SUCCESS )
{
SetLastError( RtlNtStatusToDosError( ntstatus ) );
goto ErrorExit;
}
if ( lpdwSubordinateCount != NULL )
{
*lpdwSubordinateCount = dsobj.subordinateCount;
}
if (!(szWin95ClassName = AllocateUnicodeString(dsobj.className))) {
SetLastError(ERROR_NOT_ENOUGH_MEMORY);
goto ErrorExit;
}
if ( szObjectClassName != NULL )
{
wcscpy( szObjectClassName, szWin95ClassName);
}
if (!(pszObjectName = AllocateUnicodeString(dsobj.objectName))) {
SetLastError(ERROR_NOT_ENOUGH_MEMORY);
goto ErrorExit;
}
//
// Clean up the object's relative name ...
//
if ( wcscmp( szWin95ClassName, NDS_CLASS_TOP ) )
{
LPWSTR szTempStr = pszObjectName;
while ( *szTempStr != L'=' )
{
szTempStr++;
}
szTempStr++;
wcscpy( lpNdsObject->szRelativeName, szTempStr );
szTempStr = lpNdsObject->szRelativeName;
while ( *szTempStr && *szTempStr != L'.' )
{
szTempStr++;
}
*szTempStr = L'\0';
}
else
{
wcscpy( lpNdsObject->szRelativeName, pszObjectName );
}
if ( szObjectName != NULL )
{
wcscpy( szObjectName, lpNdsObject->szRelativeName );
}
if ( szObjectFullName != NULL )
{
if ( wcscmp( szWin95ClassName, NDS_CLASS_TOP ) )
{
wcscpy( szObjectFullName, lpNdsObject->szContainerName );
wcscat( szObjectFullName, pszObjectName );
}
else
{
wcscpy( szObjectFullName,
lpNdsObject->szContainerName );
szObjectFullName[wcslen( szObjectFullName ) - 1] = L'\0';
}
}
//
// If the object is at a level below the root of the tree, append
// it full DN to handle Name.
//
if ( wcscmp( szWin95ClassName, NDS_CLASS_TOP ) )
{
wcscat(lpNdsObject->szContainerName, pszObjectName);
}
if(szWin95ClassName){
FreeUnicodeString(szWin95ClassName);
}
if(pszObjectName){
FreeUnicodeString(pszObjectName);
}
}
lpNdsObject->Signature = NDS_SIGNATURE;
*lphObject = (HANDLE) lpNdsObject;
return NO_ERROR;
#endif
ErrorExit:
if ( lpNdsObject )
{
#ifndef WIN95
// There is no ref count in Win95, the connection will time out itself
if ( lpNdsObject->NdsTree )
CloseHandle( lpNdsObject->NdsTree );
#endif
(void) LocalFree( (HLOCAL) lpNdsObject );
}
#ifdef WIN95
if(szWin95ClassName)
{
FreeUnicodeString(szWin95ClassName);
}
if(pszObjectName)
{
FreeUnicodeString(pszObjectName);
}
#endif
*lphObject = NULL;
return (DWORD) UNSUCCESSFUL;
}
DWORD
NwNdsPutInBuffer(
IN LPWSTR szAttributeName,
IN DWORD dwSyntaxID,
IN LPVOID lpAttributeValues,
IN DWORD dwValueCount,
IN DWORD dwAttrModificationOperation,
IN OUT HANDLE hOperationData )
/*
NwNdsPutInBuffer()
This function is used to add an entry to the buffer used to describe
an object attribute or change to an object attribute. The buffer must
be created using NwNdsCreateBuffer. If the buffer was created using the
operations, NDS_OBJECT_ADD, NDS_SCHEMA_DEFINE_CLASS,
NDS_SCHEMA_READ_ATTR_DEF, or NDS_SCHEMA_READ_CLASS_DEF, then
dwAttrModificationOperation is ignored. If the buffer was created using
either the operation NDS_OBJECT_READ or NDS_SEARCH, then
dwAttrModificationOperation, puAttributeType, and lpAttributeValue are
all ingnored.
Arguments:
LPWSTR szAttributeName - A NULL terminated WCHAR string
that contains name of the attribute value to be
added to the buffer. It can be a user supplied
string, or one of the many defined string macros
in ndsnames.h.
DWORD dwSyntaxID - The ID of the syntax structure used to
represent the attribute value. Syntax IDs and their
associated structures are defined in the file
NdsSntx.h. According to the NetWare NDS schema spec,
there is and always will be, only 28 (0..27)
different syntaxes.
LPVOID lpAttributeValues - A pointer to the beginning of a
buffer containing the value(s) for a particular
object attribute with data syntax dwSyntaxID.
DWORD dwValueCount - The number of value entries found in
buffer pointed to by lpAttributeValues.
DWORD dwAttrModificationOperation - If the buffer was created
using the operation NDS_MODIFY_OBJECT, then this is
used to desribe which type of modification operation
to apply for a given attribute. These attribute
modification operations are defined near the beginning
of this file.
HANDLE hOperationData - A handle to data created by
calling NwNdsCreateBuffer. The buffer stores the
attributes used to define transactions for
NwNdsAddObject, NwNdsModifyObject, NwNdsReadObject,
NwNdsReadAttrDef, NwNdsReadClassDef, or NwNdsSearch.
Returns:
NO_ERROR
ERROR_NOT_ENOUGH_MEMORY
ERROR_INVALID_PARAMETER
*/
{
LPNDS_BUFFER lpNdsBuffer = (LPNDS_BUFFER) hOperationData;
DWORD LengthInBytes;
LPBYTE lpTempEntry = NULL;
UNICODE_STRING AttributeName;
DWORD bufferSize = TWO_KB;
if ( lpNdsBuffer == NULL ||
szAttributeName == NULL ||
lpNdsBuffer->dwBufferId != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
RtlInitUnicodeString( &AttributeName, szAttributeName );
//
// Check to see if the buffer was already used by a read operation.
//
if ( lpNdsBuffer->lpReplyBuffer )
{
SetLastError( ERROR_ACCESS_DENIED );
return NDS_ERR_NO_ACCESS;
}
if ( lpNdsBuffer->dwOperation == NDS_OBJECT_MODIFY )
{
switch( dwAttrModificationOperation )
{
case NDS_ATTR_ADD:
case NDS_ATTR_REMOVE:
case NDS_ATTR_ADD_VALUE:
case NDS_ATTR_REMOVE_VALUE:
case NDS_ATTR_ADDITIONAL_VALUE:
case NDS_ATTR_OVERWRITE_VALUE:
case NDS_ATTR_CLEAR:
case NDS_ATTR_CLEAR_VALUE:
break;
default:
#if DBG
KdPrint(( "NDS32: NwNdsPutInBuffer was passed an unidentified modification operation.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
}
if ( lpNdsBuffer->dwOperation == NDS_OBJECT_ADD ||
lpNdsBuffer->dwOperation == NDS_OBJECT_MODIFY )
{
bufferSize += CalculateValueDataSize ( dwSyntaxID,
lpAttributeValues,
dwValueCount );
}
lpTempEntry = LocalAlloc( LPTR, bufferSize );
if ( ! lpTempEntry )
{
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
switch ( lpNdsBuffer->dwOperation )
{
case NDS_OBJECT_ADD:
PrepareAddEntry( lpTempEntry,
AttributeName,
dwSyntaxID,
lpAttributeValues,
dwValueCount,
&LengthInBytes );
break;
case NDS_OBJECT_MODIFY:
PrepareModifyEntry( lpTempEntry,
AttributeName,
dwSyntaxID,
dwAttrModificationOperation,
lpAttributeValues,
dwValueCount,
&LengthInBytes );
break;
case NDS_OBJECT_READ:
case NDS_SCHEMA_DEFINE_CLASS:
case NDS_SCHEMA_READ_ATTR_DEF:
case NDS_SCHEMA_READ_CLASS_DEF:
case NDS_SEARCH:
//
// Check to see if this buffer has already been used. If so,
// return with error.
//
if ( lpNdsBuffer->lpReplyBuffer )
{
if ( lpTempEntry )
LocalFree( lpTempEntry );
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
PrepareReadEntry( lpTempEntry,
AttributeName,
&LengthInBytes );
break;
default:
#if DBG
KdPrint(( "NDS32: NwNdsPutInBuffer has unknown buffer operation!\n" ));
#endif
if ( lpTempEntry )
LocalFree( lpTempEntry );
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
if ( lpNdsBuffer->dwRequestAvailableBytes >= LengthInBytes )
{
//
// Copy temporary buffer entry into buffer and update buffer header.
//
RtlCopyMemory( (LPBYTE)&lpNdsBuffer->lpRequestBuffer[lpNdsBuffer->dwLengthOfRequestData],
lpTempEntry,
LengthInBytes );
lpNdsBuffer->dwRequestAvailableBytes -= LengthInBytes;
lpNdsBuffer->dwNumberOfRequestEntries += 1;
lpNdsBuffer->dwLengthOfRequestData += LengthInBytes;
}
else
{
LPBYTE lpNewBuffer = NULL;
//
// Need to reallocate buffer to a bigger size.
//
lpNewBuffer = (LPBYTE) LocalAlloc(
LPTR,
lpNdsBuffer->dwRequestBufferSize +
LengthInBytes +
TWO_KB );
if ( lpNewBuffer == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsPutInBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
if ( lpTempEntry )
LocalFree( lpTempEntry );
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
RtlCopyMemory( lpNewBuffer,
lpNdsBuffer->lpRequestBuffer,
lpNdsBuffer->dwLengthOfRequestData );
LocalFree( (HLOCAL) lpNdsBuffer->lpRequestBuffer );
lpNdsBuffer->lpRequestBuffer = lpNewBuffer;
lpNdsBuffer->dwRequestBufferSize += LengthInBytes + TWO_KB;
lpNdsBuffer->dwRequestAvailableBytes += LengthInBytes + TWO_KB;
//
// Copy temporary buffer entry into the resized buffer and
// update buffer header.
//
RtlCopyMemory( (LPBYTE)&lpNdsBuffer->lpRequestBuffer[lpNdsBuffer->dwLengthOfRequestData],
lpTempEntry,
LengthInBytes );
lpNdsBuffer->dwRequestAvailableBytes -= LengthInBytes;
lpNdsBuffer->dwNumberOfRequestEntries += 1;
lpNdsBuffer->dwLengthOfRequestData += LengthInBytes;
}
if ( lpTempEntry )
LocalFree( lpTempEntry );
return NO_ERROR;
}
DWORD
NwNdsReadAttrDef(
IN HANDLE hTree,
IN DWORD dwInformationType, // NDS_INFO_NAMES
// or NDS_INFO_NAMES_DEFS
IN OUT HANDLE * lphOperationData OPTIONAL )
/*
NwNdsReadAttrDef()
This function is used to read attribute definitions in the schema of an
NDS directory tree.
Arguments:
HANDLE hTree - A handle to the directory tree to be
manipulated. Handle is obtained by calling
NwNdsOpenObject.
DWORD dwInformationType - Indicates whether user chooses to
read only the defined attribute name(s) in the schema or
read both the attribute name(s) and definition(s)
from the schema.
HANDLE * lphOperationData - The address of a HANDLE to data
containing a list of attribute names to be read from
the schema. This handle is manipulated by the following
functions:
NwNdsCreateBuffer (NDS_SCHEMA_READ_ATTR_DEF),
NwNdsPutInBuffer, and NwNdsFreeBuffer.
- OR -
The address of a HANDLE set to NULL, which indicates
that all attributes should be read from the schema.
If these calls are successful, this handle will also
contain the read results from the call. In the later
case, a buffer will be created to contain the read
results. Attribute values can be retrieved from the
buffer with the functions:
NwNdsGetAttrDefListFromBuffer.
After the call to this function, this buffer is ONLY
manipulated by the functions:
NwNdsGetAttrDefListFromBuffer and NwNdsFreeBuffer.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
if ( hTree == NULL ||
((LPNDS_OBJECT_PRIV) hTree)->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
if ( *lphOperationData == NULL ) // If TRUE, we need to read all attr defs
return ReadAttrDef_AllAttrs( hTree,
dwInformationType,
lphOperationData );
else // Else, we read the attr definitions specified in lphOperationData
return ReadAttrDef_SomeAttrs( hTree,
dwInformationType,
lphOperationData );
}
DWORD
NwNdsReadClassDef(
IN HANDLE hTree,
IN DWORD dwInformationType, // NDS_INFO_NAMES,
// NDS_INFO_NAMES_DEFS,
// NDS_CLASS_INFO_EXPANDED_DEFS,
// or NDS_CLASS_INFO
IN OUT HANDLE * lphOperationData OPTIONAL )
/*
NwNdsReadClassDef()
This function is used to read class definitions in the schema of an
NDS directory tree.
Arguments:
HANDLE hTree - A handle to the directory tree to be
manipulated. Handle is obtained by calling
NwNdsOpenObject.
DWORD dwInformationType - Indicates whether user chooses to
read only the defined class name(s) in the schema or
read both the class name(s) and definition(s)
from the schema.
HANDLE * lphOperationData - The address of a HANDLE to data
containing a list of class names to be read from
the schema. This handle is manipulated by the following
functions:
NwNdsCreateBuffer (NDS_SCHEMA_READ_CLASS_DEF),
NwNdsPutInBuffer, and NwNdsFreeBuffer.
- OR -
The address of a HANDLE set to NULL, which indicates
that all classes should be read from the schema.
If these calls are successful, this handle will also
contain the read results from the call. In the later
case, a buffer will be created to contain the read
results. Class read results can be retrieved from the
buffer with the functions:
NwNdsGetClassDefListFromBuffer.
After the call to this function, this buffer is ONLY
manipulated by the functions:
NwNdsGetClassDefListFromBuffer and NwNdsFreeBuffer.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
if ( hTree == NULL ||
((LPNDS_OBJECT_PRIV) hTree)->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
if ( *lphOperationData == NULL ) // If TRUE, we need to read all class defs
return ReadClassDef_AllClasses( hTree,
dwInformationType,
lphOperationData );
else // Else, we read the class definitions specified in lphOperationData
return ReadClassDef_SomeClasses( hTree,
dwInformationType,
lphOperationData );
}
DWORD
NwNdsReadObject(
IN HANDLE hObject,
IN DWORD dwInformationType, // NDS_INFO_NAMES
// or NDS_INFO_ATTR_NAMES_VALUES
IN OUT HANDLE * lphOperationData OPTIONAL )
/*
NwNdsReadObject()
This function is used to read attributes about an object of an NDS
directory tree.
Arguments:
HANDLE hObject - A handle to the object in the directory
tree to be manipulated. Handle is obtained by calling
NwNdsOpenObject.
DWORD dwInformationType - Indicates whether user chooses to
read only the attribute name(s) on the object or
read both the attribute name(s) and value(s)
from the object.
HANDLE * lphOperationData - The address of a HANDLE to data
containing a list of attributes to be read from the
object hObject. This handle is manipulated by the
following functions:
NwNdsCreateBuffer (NDS_OBJECT_READ),
NwNdsPutInBuffer, and NwNdsFreeBuffer.
- OR -
The address of a HANDLE set to NULL, which indicates
that all object attributes should be read from object
hObject.
If these calls are successful, this pointer will also
contain the read results from the call. In the later
case, a buffer will be created to contain the read
results. Attribute values can be retrieved from the
buffer with the functions:
NwNdsGetAttrListFromBuffer
After the call to this function, this buffer is ONLY
manipulated by the functions:
NwNdsGetAttrListFromBuffer and NwNdsFreeBuffer.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
if ( hObject == NULL ||
((LPNDS_OBJECT_PRIV) hObject)->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
if ( *lphOperationData == NULL ) // If TRUE, we need to read all attributes
return ReadObject_AllAttrs( hObject,
dwInformationType,
lphOperationData );
else // Else, we read the attributes specified in lphOperationData
return ReadObject_SomeAttrs( hObject,
dwInformationType,
lphOperationData );
}
DWORD
NwNdsRemoveObject(
IN HANDLE hParentObject,
IN LPWSTR szObjectName )
/*
NwNdsRemoveObject()
This function is used to remove a leaf object from an NDS directory tree.
Arguments:
HANDLE hParentObject - A handle to the parent object container
in the directory tree to remove leaf object from.
Handle is obtained by calling NwNdsOpenObject.
LPWSTR szObjectName - The directory name of the leaf object
to be removed.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD nwstatus;
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_SUCCESS;
DWORD dwReplyLength;
BYTE NdsReply[TWO_KB]; // A 2K buffer is plenty for a response
LPNDS_OBJECT_PRIV lpNdsParentObject = (LPNDS_OBJECT_PRIV) hParentObject;
LPNDS_OBJECT_PRIV lpNdsObject = NULL;
LPWSTR szFullObjectDN = NULL;
LPWSTR szTempStr = NULL;
DWORD length;
UNICODE_STRING ObjectName;
if ( szObjectName == NULL ||
lpNdsParentObject == NULL ||
lpNdsParentObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
RtlInitUnicodeString( &ObjectName, szObjectName );
//
// Create a buffer to hold the full object distinguished name.
// \\tree\<--Object Name-->.<existing container path, if any>
//
szFullObjectDN = (LPWSTR) LocalAlloc(
LPTR,
( wcslen( lpNdsParentObject->szContainerName ) *
sizeof(WCHAR) ) + // Container name
ObjectName.Length + // Object name
( 2 * sizeof(WCHAR) ) ); // Extras
//
// Check that the memory allocation was successful.
//
if ( szFullObjectDN == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsRemoveObject LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
return ERROR_NOT_ENOUGH_MEMORY;
}
length = ParseNdsUncPath( &szTempStr,
lpNdsParentObject->szContainerName,
PARSE_NDS_GET_TREE_NAME );
length /= sizeof(WCHAR);
wcscpy( szFullObjectDN, L"\\\\" ); // <\\>
wcsncat( szFullObjectDN, szTempStr, length ); // <\\tree>
wcscat( szFullObjectDN, L"\\" ); // <\\tree\>
wcsncat( szFullObjectDN, ObjectName.Buffer,
ObjectName.Length ); // <\\tree\obj>
length = ParseNdsUncPath( &szTempStr,
lpNdsParentObject->szContainerName,
PARSE_NDS_GET_PATH_NAME );
if ( length > 0 )
{
length /= sizeof(WCHAR);
wcscat( szFullObjectDN, L"." ); // <\\tree\obj.>
wcsncat( szFullObjectDN, szTempStr, length );// <\\tree\obj.org_unt.org>
}
status = NwNdsOpenObject( szFullObjectDN,
NULL,
NULL,
(HANDLE *) &lpNdsObject,
NULL,
NULL,
NULL,
NULL,
NULL );
if ( status != NO_ERROR )
{
// NwNdsOpenObject will have already set the last error . . .
goto ErrorExit;
}
(void) LocalFree( szFullObjectDN );
szFullObjectDN = NULL;
ntstatus =
FragExWithWait(
lpNdsParentObject->NdsTree,
NETWARE_NDS_FUNCTION_REMOVE_OBJECT,
NdsReply, // Response buffer.
sizeof(NdsReply), // Size of response buffer.
&dwReplyLength, // Length of response returned.
"DD", // Going to send 2 DWORDs, they are ...
0, // Version
lpNdsObject->ObjectId // The id of the object
);
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsRemoveObject: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
goto ErrorExit;
}
(void) NwNdsCloseObject( (HANDLE) lpNdsObject );
lpNdsObject = NULL;
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsRemoveObject: The remove object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
goto ErrorExit;
}
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
ErrorExit :
if ( szFullObjectDN )
{
(void) LocalFree( szFullObjectDN );
}
if ( lpNdsObject )
{
(void) NwNdsCloseObject( (HANDLE) lpNdsObject );
}
return (DWORD) UNSUCCESSFUL;
}
DWORD
NwNdsRenameObject(
IN HANDLE hParentObject,
IN LPWSTR szObjectName,
IN LPWSTR szNewObjectName,
IN BOOL fDeleteOldName )
/*
NwNdsRenameObject()
This function is used to rename an object in a NDS directory tree.
Arguments:
HANDLE hParentObject - A handle to the parent object container
in the directory tree to rename leaf object in.
Handle is obtained by calling NwNdsOpenObject.
LPWSTR szObjectName - The directory name of the object to be
renamed.
LPWSTR szNewObjectName - The new directory name of the object.
BOOL fDeleteOldName - If true, the old name is discarded;
Otherwise, the old name is retained as an additional
attribute.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD nwstatus;
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_SUCCESS;
DWORD dwReplyLength;
BYTE NdsReply[TWO_KB]; // A 2K buffer is plenty for a response
LPNDS_OBJECT_PRIV lpNdsParentObject = (LPNDS_OBJECT_PRIV) hParentObject;
LPNDS_OBJECT_PRIV lpNdsObject = NULL;
LPWSTR szFullObjectDN = NULL;
LPWSTR szTempStr = NULL;
DWORD length;
UNICODE_STRING ObjectName;
UNICODE_STRING NewObjectName;
if ( szObjectName == NULL ||
szNewObjectName == NULL ||
lpNdsParentObject == NULL ||
lpNdsParentObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
RtlInitUnicodeString( &ObjectName, szObjectName );
RtlInitUnicodeString( &NewObjectName, szNewObjectName );
//
// Create a buffer to hold the full object distinguished name.
// \\tree\<--Object Name-->.<existing container path, if any>
//
szFullObjectDN = (LPWSTR) LocalAlloc(
LPTR,
( wcslen( lpNdsParentObject->szContainerName ) *
sizeof(WCHAR) ) + // Container name
ObjectName.Length + // Object name
( 2 * sizeof(WCHAR) ) ); // Extras
//
// Check that the memory allocation was successful.
//
if ( szFullObjectDN == NULL )
{
#if DBG
KdPrint(( "NDS32: NwNdsRenameObject LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
return ERROR_NOT_ENOUGH_MEMORY;
}
length = ParseNdsUncPath( &szTempStr,
lpNdsParentObject->szContainerName,
PARSE_NDS_GET_TREE_NAME );
length /= sizeof(WCHAR);
wcscpy( szFullObjectDN, L"\\\\" ); // <\\>
wcsncat( szFullObjectDN, szTempStr, length ); // <\\tree>
wcscat( szFullObjectDN, L"\\" ); // <\\tree\>
wcsncat( szFullObjectDN, ObjectName.Buffer,
ObjectName.Length ); // <\\tree\obj>
length = ParseNdsUncPath( &szTempStr,
lpNdsParentObject->szContainerName,
PARSE_NDS_GET_PATH_NAME );
if ( length > 0 )
{
length /= sizeof(WCHAR);
wcscat( szFullObjectDN, L"." ); // <\\tree\obj.>
wcsncat( szFullObjectDN, szTempStr, length );// <\\tree\obj.org_unt.org>
}
status = NwNdsOpenObject( szFullObjectDN,
NULL,
NULL,
(HANDLE *) &lpNdsObject,
NULL,
NULL,
NULL,
NULL,
NULL );
if ( status != NO_ERROR )
{
// NwNdsOpenObject will have already set the last error . . .
goto ErrorExit;
}
(void) LocalFree( szFullObjectDN );
szFullObjectDN = NULL;
ntstatus =
FragExWithWait(
lpNdsParentObject->NdsTree,
NETWARE_NDS_FUNCTION_MODIFY_RDN,
NdsReply, // Response buffer.
sizeof(NdsReply), // Size of response buffer.
&dwReplyLength, // Length of response returned.
"DDDS",
0x00000000, // Version
lpNdsObject->ObjectId,
fDeleteOldName ? 0x00021701 : 0x00021700,
&NewObjectName
);
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsRenameObject: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
goto ErrorExit;
}
(void) NwNdsCloseObject( (HANDLE) lpNdsObject );
lpNdsObject = NULL;
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsRenameObject: The rename object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
goto ErrorExit;
}
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
ErrorExit :
if ( szFullObjectDN )
{
(void) LocalFree( szFullObjectDN );
}
if ( lpNdsObject )
{
(void) NwNdsCloseObject( (HANDLE) lpNdsObject );
}
return (DWORD) UNSUCCESSFUL;
}
DWORD
NwNdsSearch(
IN HANDLE hStartFromObject,
IN DWORD dwInformationType, // NDS_INFO_NAMES
// or NDS_INFO_ATTR_NAMES_VALUES
IN DWORD dwScope,
IN BOOL fDerefAliases,
IN LPQUERY_TREE lpQueryTree,
IN OUT LPDWORD lpdwIterHandle,
IN OUT HANDLE * lphOperationData )
/*
NwNdsSearch()
This function is used to query an NDS directory tree to find objects of
a certain object type that match a specified search filter.
Arguments:
HANDLE hStartFromObject - A HANDLE to an object in the
directory tree to start search from. Handle is
obtained by calling NwNdsOpenObject.
DWORD dwInformationType - Indicates whether user chooses to
read only the attribute name(s) on the search result
objects or read both the attribute name(s) and value(s)
from the search result objects.
DWORD dwScope -
NDS_SCOPE_ONE_LEVEL - Search subordinates from given
object, one level only
NDS_SCOPE_SUB_TREE - Search from given object on down
NDS_SCOPE_BASE_LEVEL - Applies search to an object
BOOL fDerefAliases - If TRUE the search will dereference
aliased objects to the real objects and continue
to search in the aliased objects subtree. If FALSE
the search will not dereference aliases.
LPQUERY_TREE lpQueryTree - A pointer to the root of a
search tree which defines a query. This tree
is manipulated by the following functions:
NwNdsCreateQueryNode, NwNdsDeleteQueryNode,
and NwNdsDeleteQueryTree.
LPDWORD lpdwIterHandle - A pointer to a DWORD that has the
iteration handle value. On input, the handle value
is set to NDS_INITIAL_SEARCH or to a value previously
returned from a prior call to NwNdsSearch. On ouput,
the handle value is set to NDS_NO_MORE_ITERATIONS if
search is complete, or to some other value otherwise.
HANDLE * lphOperationData - The address of a HANDLE to data
containing a list of attributes to be read from the
objects that meet the search query. This handle is
manipulated by the following functions:
NwNdsCreateBuffer (NDS_SEARCH),
NwNdsPutInBuffer, and NwNdsFreeBuffer.
- OR -
The address of a HANDLE set to NULL, which indicates
that all object attributes should be read from the
search objects found.
If these calls are successful, this handle will also
contain the read results from the call. In the later
case, a buffer will be created to contain the read
results. Object information with attribute information
can be retrieved from the buffer with the function:
NwNdsGetObjectListFromBuffer.
After the call to this function, this buffer is ONLY
manipulated by the functions:
NwNdsGetObjectListFromBuffer,
and NwNdsFreeBuffer.
Returns:
NO_ERROR
UNSUCCESSFUL - Call GetLastError for Win32 error code.
*/
{
DWORD dwNdsScope = NDS_SEARCH_SUBTREE;
switch ( dwScope )
{
case NDS_SCOPE_ONE_LEVEL :
dwNdsScope = NDS_SEARCH_SUBORDINATES;
break;
case NDS_SCOPE_SUB_TREE :
dwNdsScope = NDS_SEARCH_SUBTREE;
break;
case NDS_SCOPE_BASE_LEVEL :
dwNdsScope = NDS_SEARCH_ENTRY;
break;
}
if ( hStartFromObject == NULL ||
lpQueryTree == NULL ||
lpdwIterHandle == NULL ||
((LPNDS_OBJECT_PRIV) hStartFromObject)->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
if ( *lphOperationData == NULL )
{
//
// The callee is asking for all attributes to be returned from search.
//
return Search_AllAttrs( hStartFromObject,
dwInformationType,
dwNdsScope,
fDerefAliases,
lpQueryTree,
lpdwIterHandle,
lphOperationData );
}
else if ( ((LPNDS_BUFFER) *lphOperationData)->lpRequestBuffer == NULL )
{
//
// The callee has a handle from a prior call to NwNdsSearch, and is
// still asking for all attributes to be returned from search.
//
return Search_AllAttrs( hStartFromObject,
dwInformationType,
dwNdsScope,
fDerefAliases,
lpQueryTree,
lpdwIterHandle,
lphOperationData );
}
else
{
//
// The callee has a handle that they created with calls to
// NwNdsCreateBuffer and NwNdsPutInBuffer to specify attributes
// to be returned from search or NwNdsSearch was called once before
// and we are resuming the search.
//
return Search_SomeAttrs( hStartFromObject,
dwInformationType,
dwNdsScope,
fDerefAliases,
lpQueryTree,
lpdwIterHandle,
lphOperationData );
}
}
/* Local Function Implementations */
VOID
PrepareAddEntry(
LPBYTE lpTempEntry,
UNICODE_STRING AttributeName,
DWORD dwSyntaxID,
LPBYTE lpAttributeValues,
DWORD dwValueCount,
LPDWORD lpdwLengthInBytes )
{
LPBYTE lpTemp = lpTempEntry;
DWORD dwStringLen = AttributeName.Length + sizeof(WCHAR);
DWORD dwPadLen = ROUND_UP_COUNT( dwStringLen, ALIGN_DWORD ) -
dwStringLen;
*lpdwLengthInBytes = 0;
//
// tommye - MS bug 71653 - added try/except wrapper
//
try {
//
// Write attribute name length to temp entry buffer.
//
* (LPDWORD) lpTemp = dwStringLen;
*lpdwLengthInBytes += sizeof(DWORD);
lpTemp += sizeof(DWORD);
//
// Write attribute name to temp entry buffer.
//
RtlCopyMemory( lpTemp, AttributeName.Buffer, AttributeName.Length );
*lpdwLengthInBytes += AttributeName.Length;
lpTemp += AttributeName.Length;
//
// Add the null character.
//
* (LPWSTR) lpTemp = L'\0';
*lpdwLengthInBytes += sizeof(WCHAR);
lpTemp += sizeof(WCHAR);
//
// Write padding (if needed) to temp entry buffer.
//
if ( dwPadLen )
{
RtlZeroMemory( lpTemp, dwPadLen );
lpTemp += dwPadLen;
*lpdwLengthInBytes += dwPadLen;
}
} except ( EXCEPTION_EXECUTE_HANDLER ) {
return;
}
//
// Now add the value(s) to temp entry.
//
AppendValueToEntry( lpTemp,
dwSyntaxID,
lpAttributeValues,
dwValueCount,
lpdwLengthInBytes );
}
VOID
PrepareModifyEntry(
LPBYTE lpTempEntry,
UNICODE_STRING AttributeName,
DWORD dwSyntaxID,
DWORD dwAttrModificationOperation,
LPBYTE lpAttributeValues,
DWORD dwValueCount,
LPDWORD lpdwLengthInBytes )
{
LPBYTE lpTemp = lpTempEntry;
DWORD dwStringLen = AttributeName.Length + sizeof(WCHAR);
DWORD dwPadLen = ROUND_UP_COUNT( dwStringLen, ALIGN_DWORD ) -
dwStringLen;
*lpdwLengthInBytes = 0;
//
// tommye - MS bug 71654 - added try/except wrapper
//
try {
//
// Write attribute modification operation to temp entry buffer.
//
* (LPDWORD) lpTemp = dwAttrModificationOperation;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
//
// Write attribute name length to temp entry buffer.
//
* (LPDWORD) lpTemp = dwStringLen;
*lpdwLengthInBytes += sizeof(DWORD);
lpTemp += sizeof(DWORD);
//
// Write attribute name to temp entry buffer.
//
RtlCopyMemory( lpTemp, AttributeName.Buffer, AttributeName.Length );
*lpdwLengthInBytes += AttributeName.Length;
lpTemp += AttributeName.Length;
//
// Add the null character.
//
* (LPWSTR) lpTemp = L'\0';
*lpdwLengthInBytes += sizeof(WCHAR);
lpTemp += sizeof(WCHAR);
//
// Write padding (if needed) to temp entry buffer.
//
if ( dwPadLen )
{
RtlZeroMemory( lpTemp, dwPadLen );
lpTemp += dwPadLen;
*lpdwLengthInBytes += dwPadLen;
}
} except ( EXCEPTION_EXECUTE_HANDLER ) {
return;
}
//
// Now add the value(s) to temp entry (if needed).
//
switch( dwAttrModificationOperation )
{
case NDS_ATTR_ADD_VALUE:
case NDS_ATTR_ADDITIONAL_VALUE:
case NDS_ATTR_OVERWRITE_VALUE:
case NDS_ATTR_REMOVE_VALUE:
case NDS_ATTR_CLEAR_VALUE:
case NDS_ATTR_ADD:
AppendValueToEntry( lpTemp,
dwSyntaxID,
lpAttributeValues,
dwValueCount,
lpdwLengthInBytes );
break;
case NDS_ATTR_REMOVE:
case NDS_ATTR_CLEAR:
// Don't need to do anything for these modification operations.
break;
default :
#if DBG
KdPrint(( "NDS32: PrepareModifyEntry warning, unknown modification operation 0x%.8X\n", dwAttrModificationOperation ));
ASSERT( FALSE );
#endif
; // Nothing, skip it.
}
}
VOID
PrepareReadEntry(
LPBYTE lpTempEntry,
UNICODE_STRING AttributeName,
LPDWORD lpdwLengthInBytes )
{
LPBYTE lpTemp = lpTempEntry;
DWORD dwStringLen = AttributeName.Length + sizeof(WCHAR);
DWORD dwPadLen = ROUND_UP_COUNT( dwStringLen, ALIGN_DWORD ) -
dwStringLen;
*lpdwLengthInBytes = 0;
//
// tommye - MS bug 71655 - added try/except wrapper
//
try {
//
// Write attribute name length to temp entry buffer.
//
* (LPDWORD) lpTemp = dwStringLen;
*lpdwLengthInBytes += sizeof(DWORD);
lpTemp += sizeof(DWORD);
//
// Write attribute name to temp entry buffer.
//
RtlCopyMemory( lpTemp, AttributeName.Buffer, AttributeName.Length );
*lpdwLengthInBytes += AttributeName.Length;
lpTemp += AttributeName.Length;
//
// Add the null character.
//
* (LPWSTR) lpTemp = L'\0';
*lpdwLengthInBytes += sizeof(WCHAR);
lpTemp += sizeof(WCHAR);
//
// Write padding (if needed) to temp entry buffer.
//
if ( dwPadLen )
{
RtlZeroMemory( lpTemp, dwPadLen );
lpTemp += dwPadLen;
*lpdwLengthInBytes += dwPadLen;
}
} except ( EXCEPTION_EXECUTE_HANDLER ) {
return;
}
}
DWORD
CalculateValueDataSize(
DWORD dwSyntaxId,
LPBYTE lpAttributeValues,
DWORD dwValueCount )
{
LPBYTE lpAttrStart, lpAttrTemp = lpAttributeValues;
LPBYTE lpField1, lpField2;
DWORD numFields;
DWORD length = 0;
DWORD stringLen, stringLen2;
DWORD iter, i;
DWORD dwLengthInBytes = 0;
dwLengthInBytes += sizeof(DWORD);
for ( iter = 0; iter < dwValueCount; iter++ )
{
switch ( dwSyntaxId )
{
case NDS_SYNTAX_ID_0 :
break;
case NDS_SYNTAX_ID_1 :
case NDS_SYNTAX_ID_2 :
case NDS_SYNTAX_ID_3 :
case NDS_SYNTAX_ID_4 :
case NDS_SYNTAX_ID_5 :
case NDS_SYNTAX_ID_10 :
case NDS_SYNTAX_ID_20 :
stringLen = wcslen(((LPASN1_TYPE_1) lpAttrTemp)->DNString);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_1);
break;
case NDS_SYNTAX_ID_6 :
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
lpAttrStart = lpAttrTemp;
while( ((LPASN1_TYPE_6) lpAttrTemp)->Next )
{
stringLen = wcslen(((LPASN1_TYPE_6) lpAttrTemp)->String);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*
sizeof(WCHAR),
ALIGN_DWORD);
lpAttrTemp = (LPBYTE)(((LPASN1_TYPE_6) lpAttrTemp)->Next);
}
stringLen = wcslen(((LPASN1_TYPE_6) lpAttrTemp)->String);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*
sizeof(WCHAR),
ALIGN_DWORD);
lpAttrTemp = lpAttrStart + sizeof(ASN1_TYPE_6);
break;
case NDS_SYNTAX_ID_7 :
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_7);
break;
case NDS_SYNTAX_ID_8 :
case NDS_SYNTAX_ID_22 :
case NDS_SYNTAX_ID_24 :
case NDS_SYNTAX_ID_27 :
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_8);
break;
case NDS_SYNTAX_ID_9 :
stringLen = ((LPASN1_TYPE_9) lpAttrTemp)->Length;
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen)*sizeof(BYTE),
ALIGN_DWORD );
lpAttrTemp += sizeof(ASN1_TYPE_9);
break;
case NDS_SYNTAX_ID_11 :
stringLen = wcslen(((LPASN1_TYPE_11) lpAttrTemp)->TelephoneNumber);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD );
dwLengthInBytes += 2*sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_11);
break;
case NDS_SYNTAX_ID_12 :
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ((LPASN1_TYPE_12)
lpAttrTemp)->AddressLength * sizeof(WCHAR);
lpAttrTemp += sizeof(ASN1_TYPE_12);
break;
case NDS_SYNTAX_ID_13 :
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
lpAttrStart = lpAttrTemp;
while ( ((LPASN1_TYPE_13) lpAttrTemp)->Next )
{
stringLen = ((LPASN1_TYPE_13) lpAttrTemp)->Length;
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*
sizeof(BYTE),
ALIGN_DWORD);
lpAttrTemp = (LPBYTE)(((LPASN1_TYPE_13) lpAttrTemp)->Next);
}
stringLen = ((LPASN1_TYPE_13) lpAttrTemp)->Length;
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*
sizeof(BYTE),
ALIGN_DWORD);
lpAttrTemp = lpAttrStart + sizeof(ASN1_TYPE_13);
break;
case NDS_SYNTAX_ID_14 :
stringLen = wcslen(((LPASN1_TYPE_14) lpAttrTemp)->Address);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_14);
break;
case NDS_SYNTAX_ID_15 :
stringLen = wcslen(((LPASN1_TYPE_15) lpAttrTemp)->VolumeName);
stringLen2 = wcslen(((LPASN1_TYPE_15) lpAttrTemp)->Path);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen2+1)*sizeof(WCHAR),
ALIGN_DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_15);
break;
case NDS_SYNTAX_ID_16 :
stringLen = wcslen(((LPASN1_TYPE_16) lpAttrTemp)->ServerName);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_16);
break;
case NDS_SYNTAX_ID_17 :
stringLen = wcslen(((LPASN1_TYPE_17) lpAttrTemp)->ProtectedAttrName);
stringLen2 = wcslen(((LPASN1_TYPE_17) lpAttrTemp)->SubjectName);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen2+1)*sizeof(WCHAR),
ALIGN_DWORD);
dwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_17);
break;
case NDS_SYNTAX_ID_18 :
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
for ( i = 0; i < 6; i++ )
{
stringLen = wcslen(((LPASN1_TYPE_18) lpAttrTemp)->PostalAddress[i]);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*
sizeof(WCHAR),
ALIGN_DWORD);
}
lpAttrTemp += sizeof(ASN1_TYPE_18);
break;
case NDS_SYNTAX_ID_19 :
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_19);
break;
case NDS_SYNTAX_ID_21 :
dwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_21);
break;
case NDS_SYNTAX_ID_23 :
break;
case NDS_SYNTAX_ID_25 :
stringLen = wcslen(((LPASN1_TYPE_25) lpAttrTemp)->ObjectName);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
dwLengthInBytes += sizeof(DWORD);
dwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_25);
break;
case NDS_SYNTAX_ID_26 :
break;
default :
#if DBG
KdPrint(( "NDS32: CalculateValueDataSize() unknown SyntaxId 0x%.8X.\n", dwSyntaxId ));
ASSERT( FALSE );
#endif
break; // empty statement not allowed
}
}
return dwLengthInBytes;
}
VOID
AppendValueToEntry(
LPBYTE lpBuffer,
DWORD dwSyntaxId,
LPBYTE lpAttributeValues,
DWORD dwValueCount,
LPDWORD lpdwLengthInBytes )
{
LPBYTE lpTemp = lpBuffer;
LPBYTE lpAttrStart, lpAttrTemp = lpAttributeValues;
LPBYTE lpField1, lpField2;
DWORD numFields;
DWORD length = 0;
DWORD stringLen, stringLen2;
DWORD iter, i;
*(LPDWORD)lpTemp = dwValueCount;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
for ( iter = 0; iter < dwValueCount; iter++ )
{
switch ( dwSyntaxId )
{
case NDS_SYNTAX_ID_0 :
break;
case NDS_SYNTAX_ID_1 :
case NDS_SYNTAX_ID_2 :
case NDS_SYNTAX_ID_3 :
case NDS_SYNTAX_ID_4 :
case NDS_SYNTAX_ID_5 :
case NDS_SYNTAX_ID_10 :
case NDS_SYNTAX_ID_20 :
stringLen = wcslen(((LPASN1_TYPE_1) lpAttrTemp)->DNString);
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_1) lpAttrTemp)->DNString,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_1);
break;
case NDS_SYNTAX_ID_6 :
lpField1 = lpTemp; // Save field to store the number of
// bytes following
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpField1 = 0;
lpField2 = lpTemp; // Save field to store the number of
// elements
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpField1 += sizeof(DWORD);
numFields = 0;
lpAttrStart = lpAttrTemp;
while( ((LPASN1_TYPE_6) lpAttrTemp)->Next )
{
stringLen = wcslen(((LPASN1_TYPE_6) lpAttrTemp)->String);
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpField1 += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_6) lpAttrTemp)->String,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*
sizeof(WCHAR),
ALIGN_DWORD);
*(LPDWORD)lpField1 += ROUND_UP_COUNT((stringLen+1)*
sizeof(WCHAR),
ALIGN_DWORD);
lpAttrTemp = (LPBYTE)(((LPASN1_TYPE_6) lpAttrTemp)->Next);
numFields++;
}
stringLen = wcslen(((LPASN1_TYPE_6) lpAttrTemp)->String);
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpField1 += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_6) lpAttrTemp)->String,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*
sizeof(WCHAR),
ALIGN_DWORD);
*(LPDWORD)lpField1 += ROUND_UP_COUNT((stringLen+1)*
sizeof(WCHAR),
ALIGN_DWORD);
lpAttrTemp = lpAttrStart + sizeof(ASN1_TYPE_6);
numFields++;
*(LPDWORD)lpField2 = numFields;
break;
case NDS_SYNTAX_ID_7 :
*(LPDWORD)lpTemp = 1; // Needs to have value 1, representing one byte even though it is
// padded out to four bytes.
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = 0; // This clears all bits of the DWORD
*(LPBYTE)lpTemp = (BYTE) (((LPASN1_TYPE_7)
lpAttrTemp)->Boolean);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_7);
break;
case NDS_SYNTAX_ID_8 :
case NDS_SYNTAX_ID_22 :
case NDS_SYNTAX_ID_24 :
case NDS_SYNTAX_ID_27 :
*(LPDWORD)lpTemp = 4; // Needs to have value 4, representing four bytes - already DWORD aligned.
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = ((LPASN1_TYPE_8) lpAttrTemp)->Integer;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_8);
break;
case NDS_SYNTAX_ID_9 :
stringLen = ((LPASN1_TYPE_9) lpAttrTemp)->Length;
*(LPDWORD)lpTemp = (stringLen) * sizeof(BYTE);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_9) lpAttrTemp)->OctetString,
stringLen*sizeof(BYTE) );
lpTemp += ROUND_UP_COUNT((stringLen)*sizeof(BYTE),
ALIGN_DWORD );
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen)*sizeof(BYTE),
ALIGN_DWORD );
lpAttrTemp += sizeof(ASN1_TYPE_9);
break;
case NDS_SYNTAX_ID_11 :
stringLen = wcslen(((LPASN1_TYPE_11) lpAttrTemp)->TelephoneNumber);
*(LPDWORD)lpTemp = ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD) +
( 2*sizeof(DWORD) );
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_11) lpAttrTemp)->TelephoneNumber,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD );
lpTemp += 2*sizeof(DWORD);
*lpdwLengthInBytes += 2*sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_11);
break;
case NDS_SYNTAX_ID_12 :
*(LPDWORD)lpTemp =
(2*sizeof(DWORD)) +
(((LPASN1_TYPE_12) lpAttrTemp)->AddressLength*sizeof(WCHAR));
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = ((LPASN1_TYPE_12) lpAttrTemp)->AddressType;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
//
// Write address length value to buffer
//
*(LPDWORD)lpTemp = ((LPASN1_TYPE_12) lpAttrTemp)->AddressLength;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
//
// Write the address to the buffer
//
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_12) lpAttrTemp)->Address,
((LPASN1_TYPE_12) lpAttrTemp)->AddressLength
* sizeof(WCHAR) );
lpTemp += ((LPASN1_TYPE_12) lpAttrTemp)->AddressLength *
sizeof(WCHAR);
*lpdwLengthInBytes += ((LPASN1_TYPE_12)
lpAttrTemp)->AddressLength * sizeof(WCHAR);
lpAttrTemp += sizeof(ASN1_TYPE_12);
break;
case NDS_SYNTAX_ID_13 :
lpField1 = lpTemp; // Save field to store the number of
// bytes following
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpField1 = 0;
lpField2 = lpTemp; // Save field to store the number of
// elements
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpField1 += sizeof(DWORD);
numFields = 0;
lpAttrStart = lpAttrTemp;
while ( ((LPASN1_TYPE_13) lpAttrTemp)->Next )
{
stringLen = ((LPASN1_TYPE_13) lpAttrTemp)->Length;
*(LPDWORD)lpTemp = stringLen;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpField1 += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_13) lpAttrTemp)->Data,
stringLen*sizeof(BYTE) );
lpTemp += ROUND_UP_COUNT((stringLen+1)*sizeof(BYTE),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*
sizeof(BYTE),
ALIGN_DWORD);
*(LPDWORD)lpField1 += ROUND_UP_COUNT((stringLen+1)*
sizeof(BYTE),
ALIGN_DWORD);
lpAttrTemp = (LPBYTE)(((LPASN1_TYPE_13) lpAttrTemp)->Next);
numFields++;
}
stringLen = ((LPASN1_TYPE_13) lpAttrTemp)->Length;
*(LPDWORD)lpTemp = stringLen;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpField1 += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_13) lpAttrTemp)->Data,
stringLen*sizeof(BYTE) );
lpTemp += ROUND_UP_COUNT((stringLen+1)*sizeof(BYTE),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*
sizeof(BYTE),
ALIGN_DWORD);
*(LPDWORD)lpField1 += ROUND_UP_COUNT((stringLen+1)*
sizeof(BYTE),
ALIGN_DWORD);
lpAttrTemp = lpAttrStart + sizeof(ASN1_TYPE_13);
numFields++;
*(LPDWORD)lpField2 = numFields;
break;
case NDS_SYNTAX_ID_14 :
stringLen = wcslen(((LPASN1_TYPE_14) lpAttrTemp)->Address);
*(LPDWORD)lpTemp = ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD) +
sizeof(DWORD);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = ((LPASN1_TYPE_14) lpAttrTemp)->Type;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = (stringLen + 1)*sizeof(WCHAR);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_14) lpAttrTemp)->Address,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_14);
break;
case NDS_SYNTAX_ID_15 :
stringLen = wcslen(((LPASN1_TYPE_15) lpAttrTemp)->VolumeName);
stringLen2 = wcslen(((LPASN1_TYPE_15) lpAttrTemp)->Path);
*(LPDWORD)lpTemp = ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD) +
ROUND_UP_COUNT((stringLen2+1)*sizeof(WCHAR),
ALIGN_DWORD) +
sizeof(DWORD);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = ((LPASN1_TYPE_15) lpAttrTemp)->Type;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = (stringLen+1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_15) lpAttrTemp)->VolumeName,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*(LPDWORD)lpTemp = (stringLen2+1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_15) lpAttrTemp)->Path,
stringLen2*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT((stringLen2+1)*sizeof(WCHAR),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen2+1)*sizeof(WCHAR),
ALIGN_DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_15);
break;
case NDS_SYNTAX_ID_16 :
stringLen = wcslen(((LPASN1_TYPE_16) lpAttrTemp)->ServerName);
*(LPDWORD)lpTemp = ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD) +
(4*sizeof(DWORD));
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_16) lpAttrTemp)->ServerName,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*(LPDWORD)lpTemp = ((LPASN1_TYPE_16) lpAttrTemp)->ReplicaType;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = ((LPASN1_TYPE_16) lpAttrTemp)->ReplicaNumber;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = ((LPASN1_TYPE_16) lpAttrTemp)->Count;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_16);
break;
case NDS_SYNTAX_ID_17 :
stringLen = wcslen(((LPASN1_TYPE_17) lpAttrTemp)->ProtectedAttrName);
stringLen2 = wcslen(((LPASN1_TYPE_17) lpAttrTemp)->SubjectName);
*(LPDWORD)lpTemp = ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD) +
ROUND_UP_COUNT((stringLen2+1)*sizeof(WCHAR),
ALIGN_DWORD) +
sizeof(DWORD);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_17)lpAttrTemp)->ProtectedAttrName,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*(LPDWORD)lpTemp = (stringLen2 + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_17) lpAttrTemp)->SubjectName,
stringLen2*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT((stringLen2+1)*sizeof(WCHAR),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen2+1)*sizeof(WCHAR),
ALIGN_DWORD);
*(LPDWORD)lpTemp = ((LPASN1_TYPE_17) lpAttrTemp)->Privileges;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_17);
break;
case NDS_SYNTAX_ID_18 :
lpField1 = lpTemp; // Save field to store the number of
// bytes following
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpField1 = 0;
*(LPDWORD)lpTemp = 6; // The number of postal address fields
// is always six.
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpField1 += sizeof(DWORD);
for ( i = 0; i < 6; i++ )
{
stringLen = wcslen(((LPASN1_TYPE_18) lpAttrTemp)->PostalAddress[i]);
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpField1 += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_18) lpAttrTemp)->PostalAddress[i],
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*
sizeof(WCHAR),
ALIGN_DWORD);
*(LPDWORD)lpField1 += ROUND_UP_COUNT((stringLen+1)*
sizeof(WCHAR),
ALIGN_DWORD);
}
lpAttrTemp += sizeof(ASN1_TYPE_18);
break;
case NDS_SYNTAX_ID_19 :
*(LPDWORD)lpTemp = ((LPASN1_TYPE_19) lpAttrTemp)->WholeSeconds;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = ((LPASN1_TYPE_19) lpAttrTemp)->EventID;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_19);
break;
case NDS_SYNTAX_ID_21 :
*(LPDWORD)lpTemp = ((LPASN1_TYPE_21) lpAttrTemp)->Length;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_21);
break;
case NDS_SYNTAX_ID_23 :
break;
case NDS_SYNTAX_ID_25 :
stringLen = wcslen(((LPASN1_TYPE_25) lpAttrTemp)->ObjectName);
*(LPDWORD)lpTemp = ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD) +
2*sizeof(DWORD);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
((LPASN1_TYPE_25) lpAttrTemp)->ObjectName,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*lpdwLengthInBytes += ROUND_UP_COUNT((stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
*(LPDWORD)lpTemp = ((LPASN1_TYPE_25) lpAttrTemp)->Level;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = ((LPASN1_TYPE_25) lpAttrTemp)->Interval;
lpTemp += sizeof(DWORD);
*lpdwLengthInBytes += sizeof(DWORD);
lpAttrTemp += sizeof(ASN1_TYPE_25);
break;
case NDS_SYNTAX_ID_26 :
break;
default :
#if DBG
KdPrint(( "NDS32: AppendValueToEntry() unknown SyntaxId 0x%.8X.\n", dwSyntaxId ));
ASSERT( FALSE );
#endif
break; // empty statement not allowed
}
}
}
DWORD
MapNetwareErrorCode(
DWORD dwNetwareError )
{
DWORD status = NO_ERROR;
switch( dwNetwareError )
{
case NDS_ERR_SUCCESS :
status = NO_ERROR;
break;
case NDS_ERR_NO_SUCH_ENTRY :
case NDS_ERR_NO_SUCH_VALUE :
case NDS_ERR_NO_SUCH_ATTRIBUTE :
case NDS_ERR_NO_SUCH_CLASS :
case NDS_ERR_NO_SUCH_PARTITION :
status = ERROR_EXTENDED_ERROR;
break;
case NDS_ERR_ENTRY_ALREADY_EXISTS :
status = ERROR_ALREADY_EXISTS;
break;
case NDS_ERR_NOT_EFFECTIVE_CLASS :
case NDS_ERR_ILLEGAL_ATTRIBUTE :
case NDS_ERR_MISSING_MANDATORY :
case NDS_ERR_ILLEGAL_DS_NAME :
case NDS_ERR_ILLEGAL_CONTAINMENT :
case NDS_ERR_CANT_HAVE_MULTIPLE_VALUES :
case NDS_ERR_SYNTAX_VIOLATION :
case NDS_ERR_DUPLICATE_VALUE :
case NDS_ERR_ATTRIBUTE_ALREADY_EXISTS :
case NDS_ERR_MAXIMUM_ENTRIES_EXIST :
case NDS_ERR_DATABASE_FORMAT :
case NDS_ERR_INCONSISTANT_DATABASE :
case NDS_ERR_INVALID_COMPARISON :
case NDS_ERR_COMPARISON_FAILED :
case NDS_ERR_TRANSACTIONS_DISABLED :
case NDS_ERR_INVALID_TRANSPORT :
case NDS_ERR_SYNTAX_INVALID_IN_NAME :
case NDS_ERR_REPLICA_ALREADY_EXISTS :
case NDS_ERR_TRANSPORT_FAILURE :
case NDS_ERR_ALL_REFERRALS_FAILED :
case NDS_ERR_CANT_REMOVE_NAMING_VALUE :
case NDS_ERR_OBJECT_CLASS_VIOLATION :
case NDS_ERR_ENTRY_IS_NOT_LEAF :
case NDS_ERR_DIFFERENT_TREE :
case NDS_ERR_ILLEGAL_REPLICA_TYPE :
case NDS_ERR_SYSTEM_FAILURE :
case NDS_ERR_INVALID_ENTRY_FOR_ROOT :
case NDS_ERR_NO_REFERRALS :
case NDS_ERR_REMOTE_FAILURE :
case NDS_ERR_INVALID_REQUEST :
case NDS_ERR_INVALID_ITERATION :
case NDS_ERR_SCHEMA_IS_NONREMOVABLE :
case NDS_ERR_SCHEMA_IS_IN_USE :
case NDS_ERR_CLASS_ALREADY_EXISTS :
case NDS_ERR_BAD_NAMING_ATTRIBUTES :
case NDS_ERR_NOT_ROOT_PARTITION :
case NDS_ERR_INSUFFICIENT_STACK :
case NDS_ERR_INSUFFICIENT_BUFFER :
case NDS_ERR_AMBIGUOUS_CONTAINMENT :
case NDS_ERR_AMBIGUOUS_NAMING :
case NDS_ERR_DUPLICATE_MANDATORY :
case NDS_ERR_DUPLICATE_OPTIONAL :
case NDS_ERR_MULTIPLE_REPLICAS :
case NDS_ERR_CRUCIAL_REPLICA :
case NDS_ERR_SCHEMA_SYNC_IN_PROGRESS :
case NDS_ERR_SKULK_IN_PROGRESS :
case NDS_ERR_TIME_NOT_SYNCRONIZED :
case NDS_ERR_RECORD_IN_USE :
case NDS_ERR_DS_VOLUME_NOT_MOUNTED :
case NDS_ERR_DS_VOLUME_IO_FAILURE :
case NDS_ERR_DS_LOCKED :
case NDS_ERR_OLD_EPOCH :
case NDS_ERR_NEW_EPOCH :
case NDS_ERR_PARTITION_ROOT :
case NDS_ERR_ENTRY_NOT_CONTAINER :
case NDS_ERR_FAILED_AUTHENTICATION :
case NDS_ERR_NO_SUCH_PARENT :
status = ERROR_EXTENDED_ERROR;
break;
case NDS_ERR_NO_ACCESS :
status = ERROR_ACCESS_DENIED;
break;
case NDS_ERR_REPLICA_NOT_ON :
case NDS_ERR_DUPLICATE_ACL :
case NDS_ERR_PARTITION_ALREADY_EXISTS :
case NDS_ERR_NOT_SUBREF :
case NDS_ERR_ALIAS_OF_AN_ALIAS :
case NDS_ERR_AUDITING_FAILED :
case NDS_ERR_INVALID_API_VERSION :
case NDS_ERR_SECURE_NCP_VIOLATION :
case NDS_ERR_FATAL :
status = ERROR_EXTENDED_ERROR;
break;
default :
#if DBG
KdPrint(( "NDS32: MapNetwareErrorCode failed, Netware error = 0x%.8X\n", dwNetwareError ));
ASSERT( FALSE );
#endif
status = ERROR_EXTENDED_ERROR;
}
return status;
}
DWORD
IndexReadAttrDefReplyBuffer(
LPNDS_BUFFER lpNdsBuffer )
{
LPNDS_ATTR_DEF lpReplyIndex = NULL;
DWORD iter;
LPBYTE lpByte = NULL;
DWORD dwStringLen;
//
// Make sure this is set to zero, for NwNdsGetNextXXXXFromBuffer()
//
lpNdsBuffer->dwCurrentIndexEntry = 0;
//
// Set values used to track the memory used in the index buffer.
//
lpNdsBuffer->dwIndexBufferSize = lpNdsBuffer->dwNumberOfReplyEntries *
sizeof(NDS_ATTR_DEF);
lpNdsBuffer->dwIndexAvailableBytes = lpNdsBuffer->dwIndexBufferSize;
lpNdsBuffer->dwNumberOfIndexEntries = 0;
lpNdsBuffer->dwLengthOfIndexData = 0;
//
// Create a buffer to hold the ReplyBufferIndex
//
lpReplyIndex = (LPNDS_ATTR_DEF)
LocalAlloc( LPTR, lpNdsBuffer->dwIndexBufferSize );
//
// Check that the memory allocation was successful.
//
if ( lpReplyIndex == NULL )
{
#if DBG
KdPrint(( "NDS32: IndexReadAttrDefReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
lpNdsBuffer->lpIndexBuffer = (LPBYTE) lpReplyIndex;
//
// Move lpByte so that it points to the first attribute definition
//
lpByte = lpNdsBuffer->lpReplyBuffer;
// lpByte += sizeof(DWORD); // Move past Completion Code
// lpByte += sizeof(DWORD); // Move past Iteration Handle
// lpByte += sizeof(DWORD); // Move past Information Type
// lpByte += sizeof(DWORD); // Move past Amount Of Attributes
lpByte += 4 * sizeof(DWORD); // Equivalent to above
//
// In a for loop, walk the reply buffer index and fill it up with
// data by referencing the Reply buffer or Syntax buffer.
//
for ( iter = 0; iter < lpNdsBuffer->dwNumberOfReplyEntries; iter++ )
{
dwStringLen = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Attribute Name Length
lpReplyIndex[iter].szAttributeName = (LPWSTR) lpByte;
lpByte += ROUND_UP_COUNT( dwStringLen, ALIGN_DWORD );
lpReplyIndex[iter].dwFlags = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Flags
lpReplyIndex[iter].dwSyntaxID = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Syntax ID
lpReplyIndex[iter].dwLowerLimit = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Lower Limit
lpReplyIndex[iter].dwUpperLimit = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Upper Limit
lpReplyIndex[iter].asn1ID.length = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past ASN.1 ID length
RtlCopyMemory( lpReplyIndex[iter].asn1ID.data,
lpByte,
sizeof(BYTE) * NDS_MAX_ASN1_NAME_LEN );
lpByte += sizeof(BYTE) * NDS_MAX_ASN1_NAME_LEN;
lpNdsBuffer->dwNumberOfIndexEntries++;
lpNdsBuffer->dwLengthOfIndexData += sizeof( NDS_ATTR_DEF );
lpNdsBuffer->dwIndexAvailableBytes -= sizeof( NDS_ATTR_DEF );
}
#if DBG
if ( lpNdsBuffer->dwLengthOfIndexData != lpNdsBuffer->dwIndexBufferSize )
{
KdPrint(( "ASSERT in NDS32: IndexReadAttrDefReplyBuffer\n" ));
KdPrint(( " lpNdsBuffer->dwLengthOfIndexData !=\n" ));
KdPrint(( " lpNdsBuffer->dwIndexBufferSize\n" ));
ASSERT( FALSE );
}
#endif
return NO_ERROR;
}
DWORD
IndexReadClassDefReplyBuffer(
LPNDS_BUFFER lpNdsBuffer )
{
LPNDS_CLASS_DEF lpReplyIndex = NULL;
DWORD iter;
LPBYTE lpByte = NULL;
DWORD LengthOfValueStructs;
DWORD dwStringLen;
//
// Make sure this is set to zero, for NwNdsGetNextXXXXFromBuffer()
//
lpNdsBuffer->dwCurrentIndexEntry = 0;
//
// Set values used to track the memory used in the index buffer.
//
lpNdsBuffer->dwIndexBufferSize = lpNdsBuffer->dwNumberOfReplyEntries *
sizeof(NDS_CLASS_DEF);
lpNdsBuffer->dwIndexAvailableBytes = lpNdsBuffer->dwIndexBufferSize;
lpNdsBuffer->dwNumberOfIndexEntries = 0;
lpNdsBuffer->dwLengthOfIndexData = 0;
//
// Create a buffer to hold the ReplyBufferIndex
//
lpReplyIndex = (LPNDS_CLASS_DEF)
LocalAlloc( LPTR,
lpNdsBuffer->dwIndexBufferSize );
//
// Check that the memory allocation was successful.
//
if ( lpReplyIndex == NULL )
{
#if DBG
KdPrint(( "NDS32: IndexReadClassDefReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
lpNdsBuffer->lpIndexBuffer = (LPBYTE) lpReplyIndex;
//
// Move lpByte so that it points to the SyntaxId of the first attribute
//
lpByte = lpNdsBuffer->lpReplyBuffer;
// lpByte += sizeof(DWORD); // Move past Completion Code
// lpByte += sizeof(DWORD); // Move past Iteration Handle
// lpByte += sizeof(DWORD); // Move past Information Type
// lpByte += sizeof(DWORD); // Move past Amount Of Attributes
lpByte += 4 * sizeof(DWORD); // Equivalent to above
//
// In a for loop, walk the index buffer and fill it up with
// data by referencing the reply buffer. Note references to
// the syntax buffer are stored as offsets while un-marshalling.
//
for ( iter = 0; iter < lpNdsBuffer->dwNumberOfReplyEntries; iter++ )
{
dwStringLen = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Class Name Length
lpReplyIndex[iter].szClassName = (LPWSTR) lpByte;
lpByte += ROUND_UP_COUNT( dwStringLen, ALIGN_DWORD );
lpReplyIndex[iter].dwFlags = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Flags
lpReplyIndex[iter].asn1ID.length = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past ASN.1 ID length
RtlCopyMemory( lpReplyIndex[iter].asn1ID.data,
lpByte,
sizeof(BYTE) * NDS_MAX_ASN1_NAME_LEN );
lpByte += sizeof(BYTE) * NDS_MAX_ASN1_NAME_LEN;
lpReplyIndex[iter].dwNumberOfSuperClasses = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD);
if ( lpReplyIndex[iter].dwNumberOfSuperClasses > 0 )
{
if ( VerifyBufferSizeForStringList(
lpNdsBuffer->dwSyntaxAvailableBytes,
lpReplyIndex[iter].dwNumberOfSuperClasses,
&LengthOfValueStructs ) != NO_ERROR )
{
if ( AllocateOrIncreaseSyntaxBuffer( lpNdsBuffer ) != NO_ERROR )
{
#if DBG
KdPrint(( "NDS32: IndexReadClassDefReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
}
lpByte += ParseStringListBlob(
lpByte,
lpReplyIndex[iter].dwNumberOfSuperClasses,
(LPVOID) &lpNdsBuffer->lpSyntaxBuffer[lpNdsBuffer->dwLengthOfSyntaxData] );
lpReplyIndex[iter].lpSuperClasses =
(LPWSTR_LIST) lpNdsBuffer->dwLengthOfSyntaxData;
lpNdsBuffer->dwSyntaxAvailableBytes -= LengthOfValueStructs;
lpNdsBuffer->dwLengthOfSyntaxData += LengthOfValueStructs;
}
else
{
lpReplyIndex[iter].lpSuperClasses = NULL;
}
lpReplyIndex[iter].dwNumberOfContainmentClasses = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD);
if ( lpReplyIndex[iter].dwNumberOfContainmentClasses > 0 )
{
if ( VerifyBufferSizeForStringList(
lpNdsBuffer->dwSyntaxAvailableBytes,
lpReplyIndex[iter].dwNumberOfContainmentClasses,
&LengthOfValueStructs ) != NO_ERROR )
{
if ( AllocateOrIncreaseSyntaxBuffer( lpNdsBuffer ) !=
NO_ERROR )
{
#if DBG
KdPrint(( "NDS32: IndexReadClassDefReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
}
lpByte += ParseStringListBlob(
lpByte,
lpReplyIndex[iter].dwNumberOfContainmentClasses,
(LPVOID) &lpNdsBuffer->lpSyntaxBuffer[lpNdsBuffer->dwLengthOfSyntaxData] );
lpReplyIndex[iter].lpContainmentClasses =
(LPWSTR_LIST) lpNdsBuffer->dwLengthOfSyntaxData;
lpNdsBuffer->dwSyntaxAvailableBytes -= LengthOfValueStructs;
lpNdsBuffer->dwLengthOfSyntaxData += LengthOfValueStructs;
}
else
{
lpReplyIndex[iter].lpContainmentClasses = NULL;
}
lpReplyIndex[iter].dwNumberOfNamingAttributes = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD);
if ( lpReplyIndex[iter].dwNumberOfNamingAttributes > 0 )
{
if ( VerifyBufferSizeForStringList(
lpNdsBuffer->dwSyntaxAvailableBytes,
lpReplyIndex[iter].dwNumberOfNamingAttributes,
&LengthOfValueStructs ) != NO_ERROR )
{
if ( AllocateOrIncreaseSyntaxBuffer( lpNdsBuffer ) != NO_ERROR )
{
#if DBG
KdPrint(( "NDS32: IndexReadClassDefReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
}
lpByte += ParseStringListBlob(
lpByte,
lpReplyIndex[iter].dwNumberOfNamingAttributes,
(LPVOID) &lpNdsBuffer->lpSyntaxBuffer[lpNdsBuffer->dwLengthOfSyntaxData] );
lpReplyIndex[iter].lpNamingAttributes =
(LPWSTR_LIST) lpNdsBuffer->dwLengthOfSyntaxData;
lpNdsBuffer->dwSyntaxAvailableBytes -= LengthOfValueStructs;
lpNdsBuffer->dwLengthOfSyntaxData += LengthOfValueStructs;
}
else
{
lpReplyIndex[iter].lpNamingAttributes = NULL;
}
lpReplyIndex[iter].dwNumberOfMandatoryAttributes = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD);
if ( lpReplyIndex[iter].dwNumberOfMandatoryAttributes > 0 )
{
if ( VerifyBufferSizeForStringList(
lpNdsBuffer->dwSyntaxAvailableBytes,
lpReplyIndex[iter].dwNumberOfMandatoryAttributes,
&LengthOfValueStructs ) != NO_ERROR )
{
if ( AllocateOrIncreaseSyntaxBuffer( lpNdsBuffer ) != NO_ERROR )
{
#if DBG
KdPrint(( "NDS32: IndexReadClassDefReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
}
lpByte += ParseStringListBlob(
lpByte,
lpReplyIndex[iter].dwNumberOfMandatoryAttributes,
(LPVOID) &lpNdsBuffer->lpSyntaxBuffer[lpNdsBuffer->dwLengthOfSyntaxData] );
lpReplyIndex[iter].lpMandatoryAttributes =
(LPWSTR_LIST) lpNdsBuffer->dwLengthOfSyntaxData;
lpNdsBuffer->dwSyntaxAvailableBytes -= LengthOfValueStructs;
lpNdsBuffer->dwLengthOfSyntaxData += LengthOfValueStructs;
}
else
{
lpReplyIndex[iter].lpMandatoryAttributes = NULL;
}
lpReplyIndex[iter].dwNumberOfOptionalAttributes = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD);
if ( lpReplyIndex[iter].dwNumberOfOptionalAttributes > 0 )
{
if ( VerifyBufferSizeForStringList(
lpNdsBuffer->dwSyntaxAvailableBytes,
lpReplyIndex[iter].dwNumberOfOptionalAttributes,
&LengthOfValueStructs ) != NO_ERROR )
{
if ( AllocateOrIncreaseSyntaxBuffer( lpNdsBuffer ) != NO_ERROR )
{
#if DBG
KdPrint(( "NDS32: IndexReadClassDefReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
}
lpByte += ParseStringListBlob(
lpByte,
lpReplyIndex[iter].dwNumberOfOptionalAttributes,
(LPVOID) &lpNdsBuffer->lpSyntaxBuffer[lpNdsBuffer->dwLengthOfSyntaxData] );
lpReplyIndex[iter].lpOptionalAttributes =
(LPWSTR_LIST) lpNdsBuffer->dwLengthOfSyntaxData;
lpNdsBuffer->dwSyntaxAvailableBytes -= LengthOfValueStructs;
lpNdsBuffer->dwLengthOfSyntaxData += LengthOfValueStructs;
}
else
{
lpReplyIndex[iter].lpOptionalAttributes = NULL;
}
lpNdsBuffer->dwNumberOfIndexEntries++;
lpNdsBuffer->dwLengthOfIndexData += sizeof( NDS_CLASS_DEF );
lpNdsBuffer->dwIndexAvailableBytes -= sizeof( NDS_CLASS_DEF );
}
//
// Now convert all syntax buffer references to pointers.
//
for ( iter = 0; iter < lpNdsBuffer->dwNumberOfIndexEntries; iter++ )
{
if ( lpReplyIndex[iter].dwNumberOfSuperClasses > 0 )
{
(LPBYTE) lpReplyIndex[iter].lpSuperClasses +=
(DWORD_PTR) lpNdsBuffer->lpSyntaxBuffer;
}
if ( lpReplyIndex[iter].dwNumberOfContainmentClasses > 0 )
{
(LPBYTE) lpReplyIndex[iter].lpContainmentClasses +=
(DWORD_PTR) lpNdsBuffer->lpSyntaxBuffer;
}
if ( lpReplyIndex[iter].dwNumberOfNamingAttributes > 0 )
{
(LPBYTE) lpReplyIndex[iter].lpNamingAttributes +=
(DWORD_PTR) lpNdsBuffer->lpSyntaxBuffer;
}
if ( lpReplyIndex[iter].dwNumberOfMandatoryAttributes > 0 )
{
(LPBYTE) lpReplyIndex[iter].lpMandatoryAttributes +=
(DWORD_PTR) lpNdsBuffer->lpSyntaxBuffer;
}
if ( lpReplyIndex[iter].dwNumberOfOptionalAttributes > 0 )
{
(LPBYTE) lpReplyIndex[iter].lpOptionalAttributes +=
(DWORD_PTR) lpNdsBuffer->lpSyntaxBuffer;
}
}
#if DBG
if ( lpNdsBuffer->dwLengthOfIndexData != lpNdsBuffer->dwIndexBufferSize )
{
KdPrint(( "ASSERT in NDS32: IndexReadClassDefReplyBuffer\n" ));
KdPrint(( " lpNdsBuffer->dwLengthOfIndexData !=\n" ));
KdPrint(( " lpNdsBuffer->dwIndexBufferSize\n" ));
ASSERT( FALSE );
}
#endif
return NO_ERROR;
}
DWORD
IndexReadObjectReplyBuffer(
LPNDS_BUFFER lpNdsBuffer )
{
LPNDS_ATTR_INFO lpReplyIndex = NULL;
DWORD iter;
LPBYTE lpByte = NULL;
DWORD LengthOfValueStructs;
DWORD dwStringLen;
//
// Make sure this is set to zero, for NwNdsGetNextXXXXFromBuffer()
//
lpNdsBuffer->dwCurrentIndexEntry = 0;
//
// Set values used to track the memory used in the index buffer.
//
lpNdsBuffer->dwIndexBufferSize = lpNdsBuffer->dwNumberOfReplyEntries *
sizeof(NDS_ATTR_INFO);
lpNdsBuffer->dwIndexAvailableBytes = lpNdsBuffer->dwIndexBufferSize;
lpNdsBuffer->dwNumberOfIndexEntries = 0;
lpNdsBuffer->dwLengthOfIndexData = 0;
//
// Create a buffer to hold the ReplyBufferIndex
//
lpReplyIndex = (LPNDS_ATTR_INFO)
LocalAlloc( LPTR, lpNdsBuffer->dwIndexBufferSize );
//
// Check that the memory allocation was successful.
//
if ( lpReplyIndex == NULL )
{
#if DBG
KdPrint(( "NDS32: IndexReadObjectReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
lpNdsBuffer->lpIndexBuffer = (LPBYTE) lpReplyIndex;
//
// Move lpByte so that it points to the SyntaxId of the first attribute
//
lpByte = lpNdsBuffer->lpReplyBuffer;
// lpByte += sizeof(DWORD); // Move past Completion Code
// lpByte += sizeof(DWORD); // Move past Iteration Handle
// lpByte += sizeof(DWORD); // Move past Information Type
// lpByte += sizeof(DWORD); // Move past Amount Of Attributes
lpByte += 4 * sizeof(DWORD); // Equivalent to above
//
// In a for loop, walk the index buffer and fill it up with
// data by referencing the reply buffer. Note references to
// the syntax buffer are stored as offsets while un-marshalling.
//
for ( iter = 0; iter < lpNdsBuffer->dwNumberOfReplyEntries; iter++ )
{
lpReplyIndex[iter].dwSyntaxId = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Syntax Id
dwStringLen = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Attribute Name Length
lpReplyIndex[iter].szAttributeName = (LPWSTR) lpByte;
lpByte += ROUND_UP_COUNT( dwStringLen, ALIGN_DWORD );
lpReplyIndex[iter].dwNumberOfValues = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Count Of Values
//
// See if the syntax buffer is large enough to hold the number of
// SyntaxID structures that will be used to store the value(s)
// for the current attribute. If the buffer isn't large enough
// it is reallocated to a bigger size (if possible).
//
if ( VerifyBufferSize( lpByte,
lpNdsBuffer->dwSyntaxAvailableBytes,
lpReplyIndex[iter].dwSyntaxId,
lpReplyIndex[iter].dwNumberOfValues,
&LengthOfValueStructs ) != NO_ERROR )
{
if ( AllocateOrIncreaseSyntaxBuffer( lpNdsBuffer ) != NO_ERROR )
{
#if DBG
KdPrint(( "NDS32: IndexReadObjectReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
}
//
// Parse the raw data buffer by mapping the network structures to
// the NDS Syntax structures we define in NdsSntx.h. Then move the
// pointer used to walk the raw data buffer past the ASN.1 Values.
//
lpByte += ParseASN1ValueBlob( lpByte,
lpReplyIndex[iter].dwSyntaxId,
lpReplyIndex[iter].dwNumberOfValues,
(LPVOID) &lpNdsBuffer->lpSyntaxBuffer[lpNdsBuffer->dwLengthOfSyntaxData] );
lpReplyIndex[iter].lpValue =
(LPBYTE) lpNdsBuffer->dwLengthOfSyntaxData;
lpNdsBuffer->dwSyntaxAvailableBytes -= LengthOfValueStructs;
lpNdsBuffer->dwLengthOfSyntaxData += LengthOfValueStructs;
lpNdsBuffer->dwNumberOfIndexEntries++;
lpNdsBuffer->dwLengthOfIndexData += sizeof( NDS_ATTR_INFO );
lpNdsBuffer->dwIndexAvailableBytes -= sizeof( NDS_ATTR_INFO );
}
//
// Now convert all syntax buffer references to pointers.
//
for ( iter = 0; iter < lpNdsBuffer->dwNumberOfIndexEntries; iter++ )
{
(LPBYTE) lpReplyIndex[iter].lpValue +=
(DWORD_PTR) lpNdsBuffer->lpSyntaxBuffer;
}
#if DBG
if ( lpNdsBuffer->dwLengthOfIndexData != lpNdsBuffer->dwIndexBufferSize )
{
KdPrint(( "ASSERT in NDS32: IndexReadObjectReplyBuffer\n" ));
KdPrint(( " lpNdsBuffer->dwLengthOfIndexData !=\n" ));
KdPrint(( " lpNdsBuffer->dwIndexBufferSize\n" ));
ASSERT( FALSE );
}
#endif
return NO_ERROR;
}
DWORD
IndexReadNameReplyBuffer(
LPNDS_BUFFER lpNdsBuffer )
{
LPNDS_NAME_ONLY lpReplyIndex = NULL;
DWORD iter;
LPBYTE lpByte = NULL;
DWORD dwStringLen;
//
// Make sure this is set to zero, for NwNdsGetNextXXXXFromBuffer()
//
lpNdsBuffer->dwCurrentIndexEntry = 0;
//
// Set values used to track the memory used in the index buffer.
//
lpNdsBuffer->dwIndexBufferSize = lpNdsBuffer->dwNumberOfReplyEntries *
sizeof(NDS_NAME_ONLY);
lpNdsBuffer->dwIndexAvailableBytes = lpNdsBuffer->dwIndexBufferSize;
lpNdsBuffer->dwNumberOfIndexEntries = 0;
lpNdsBuffer->dwLengthOfIndexData = 0;
//
// Create a buffer to hold the ReplyBufferIndex
//
lpReplyIndex = (LPNDS_NAME_ONLY)
LocalAlloc( LPTR, lpNdsBuffer->dwIndexBufferSize );
//
// Check that the memory allocation was successful.
//
if ( lpReplyIndex == NULL )
{
#if DBG
KdPrint(( "NDS32: IndexReadNameReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
lpNdsBuffer->lpIndexBuffer = (LPBYTE) lpReplyIndex;
//
// Move lpByte so that it points to the first name
//
lpByte = lpNdsBuffer->lpReplyBuffer;
// lpByte += sizeof(DWORD); // Move past Completion Code
// lpByte += sizeof(DWORD); // Move past Iteration Handle
// lpByte += sizeof(DWORD); // Move past Information Type
// lpByte += sizeof(DWORD); // Move past Amount Of Attributes
lpByte += 4 * sizeof(DWORD); // Equivalent to above
//
// In a for loop, walk the reply buffer index and fill it up with
// data by referencing the Reply buffer or Syntax buffer.
//
for ( iter = 0; iter < lpNdsBuffer->dwNumberOfReplyEntries; iter++ )
{
dwStringLen = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Attribute Name Length
lpReplyIndex[iter].szName = (LPWSTR) lpByte;
lpByte += ROUND_UP_COUNT( dwStringLen, ALIGN_DWORD );
lpNdsBuffer->dwNumberOfIndexEntries++;
lpNdsBuffer->dwLengthOfIndexData += sizeof( NDS_NAME_ONLY );
lpNdsBuffer->dwIndexAvailableBytes -= sizeof( NDS_NAME_ONLY );
}
#if DBG
if ( lpNdsBuffer->dwLengthOfIndexData != lpNdsBuffer->dwIndexBufferSize )
{
KdPrint(( "ASSERT in NDS32: IndexReadNameReplyBuffer\n" ));
KdPrint(( " lpNdsBuffer->dwLengthOfIndexData !=\n" ));
KdPrint(( " lpNdsBuffer->dwIndexBufferSize\n" ));
ASSERT( FALSE );
}
#endif
return NO_ERROR;
}
DWORD
IndexSearchObjectReplyBuffer(
LPNDS_BUFFER lpNdsBuffer )
{
LPNDS_OBJECT_INFO lpReplyIndex = NULL;
DWORD iter;
DWORD iter2;
LPBYTE lpByte = NULL;
DWORD LengthOfValueStructs;
DWORD dwStringLen;
LPBYTE FixedPortion;
LPWSTR EndOfVariableData;
//
// Make sure this is set to zero, for NwNdsGetNextXXXXFromBuffer()
//
lpNdsBuffer->dwCurrentIndexEntry = 0;
//
// Set values used to track the memory used in the index buffer.
//
lpNdsBuffer->dwIndexBufferSize = lpNdsBuffer->dwNumberOfReplyEntries *
( sizeof(NDS_OBJECT_INFO) +
( MAX_NDS_NAME_CHARS * 4 *
sizeof( WCHAR ) ) );
lpNdsBuffer->dwIndexAvailableBytes = lpNdsBuffer->dwIndexBufferSize;
lpNdsBuffer->dwNumberOfIndexEntries = 0;
lpNdsBuffer->dwLengthOfIndexData = 0;
//
// Create a buffer to hold the ReplyBufferIndex
//
lpReplyIndex = (LPNDS_OBJECT_INFO)
LocalAlloc( LPTR, lpNdsBuffer->dwIndexBufferSize );
//
// Check that the memory allocation was successful.
//
if ( lpReplyIndex == NULL )
{
#if DBG
KdPrint(( "NDS32: IndexSearchObjectReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
lpNdsBuffer->lpIndexBuffer = (LPBYTE) lpReplyIndex;
FixedPortion = lpNdsBuffer->lpIndexBuffer;
EndOfVariableData = (LPWSTR) ((DWORD_PTR) FixedPortion +
ROUND_DOWN_COUNT(
lpNdsBuffer->dwIndexAvailableBytes,
ALIGN_DWORD ) );
//
// Move lpByte so that it points to the first object
//
lpByte = lpNdsBuffer->lpReplyBuffer;
// lpByte += sizeof(DWORD); // Move past Completion Code
// lpByte += sizeof(DWORD); // Move past Iteration Handle
// lpByte += sizeof(DWORD); // Move past Information Type
// lpByte += sizeof(DWORD); // Move past Amount Of Attributes
// lpByte += sizeof(DWORD); // Move past Length Of Search
// lpByte += sizeof(DWORD); // Move past Amount Of Entries
lpByte += 6 * sizeof(DWORD); // Equivalent to above
//
// In a for loop, walk the reply buffer index and fill it up with
// data by referencing the Reply buffer or Syntax buffer.
//
for ( iter = 0; iter < lpNdsBuffer->dwNumberOfReplyEntries; iter++ )
{
WORD tempStrLen;
LPWSTR newPathStr = NULL;
LPWSTR tempStr = NULL;
LPWSTR ClassName;
LPWSTR DistinguishedObjectName;
LPWSTR ObjectName;
DWORD ClassNameLen;
DWORD DistinguishedObjectNameLen;
DWORD Flags;
DWORD SubordinateCount;
DWORD ModificationTime;
DWORD NumberOfAttributes = 0;
LPNDS_ATTR_INFO lpAttributeInfos = NULL;
DWORD EntryInfo1;
//
// Get current subtree data from lpNdsParentObject
//
lpByte = GetSearchResultData( lpByte,
&Flags,
&SubordinateCount,
&ModificationTime,
&ClassNameLen,
&ClassName,
&DistinguishedObjectNameLen,
&DistinguishedObjectName,
&EntryInfo1,
&NumberOfAttributes );
//
// Need to build a string with the new NDS UNC path
// for search object
//
newPathStr = (PVOID) LocalAlloc( LPTR,
( wcslen( DistinguishedObjectName ) +
wcslen( lpNdsBuffer->szPath ) +
3 ) * sizeof( WCHAR ) );
if ( newPathStr == NULL )
{
#if DBG
KdPrint(("NDS32: IndexSearchObjectReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError()));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
//
// Need to build a string for the relative object name.
//
ObjectName = (PVOID) LocalAlloc( LPTR,
( wcslen( DistinguishedObjectName ) +
1 ) * sizeof( WCHAR ) );
if ( ObjectName == NULL )
{
#if DBG
KdPrint(("NDS32: IndexSearchObjectReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError()));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
tempStrLen = ParseNdsUncPath( (LPWSTR *) &tempStr,
lpNdsBuffer->szPath,
PARSE_NDS_GET_TREE_NAME );
tempStrLen /= sizeof(WCHAR);
if ( tempStrLen > 0 )
{
wcscpy( newPathStr, L"\\\\" );
wcsncat( newPathStr, tempStr, tempStrLen );
wcscat( newPathStr, L"\\" );
wcscat( newPathStr, DistinguishedObjectName );
_wcsupr( newPathStr );
}
else
{
wcscpy( newPathStr, L"" );
}
tempStrLen = ParseNdsUncPath( (LPWSTR *) &tempStr,
newPathStr,
PARSE_NDS_GET_OBJECT_NAME );
tempStrLen /= sizeof(WCHAR);
if ( tempStrLen > 0 )
{
wcsncpy( ObjectName, tempStr, tempStrLen );
}
else
{
wcscpy( ObjectName, L"" );
}
if ( lpNdsBuffer->dwReplyInformationType == NDS_INFO_ATTR_NAMES_VALUES )
{
lpAttributeInfos = (LPNDS_ATTR_INFO) LocalAlloc(
LPTR,
NumberOfAttributes *
sizeof( NDS_ATTR_INFO )
);
if ( lpAttributeInfos == NULL )
{
#if DBG
KdPrint(("NDS32: IndexSearchObjectReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError()));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
for ( iter2 = 0; iter2 < NumberOfAttributes; iter2++ )
{
lpAttributeInfos[iter2].dwSyntaxId = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Syntax Id
dwStringLen = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Attribute Name Length
lpAttributeInfos[iter2].szAttributeName = (LPWSTR) lpByte;
lpByte += ROUND_UP_COUNT( dwStringLen, ALIGN_DWORD );
lpAttributeInfos[iter2].dwNumberOfValues = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Count Of Values
//
// See if the syntax buffer is large enough to hold the number of
// SyntaxID structures that will be used to store the value(s)
// for the current attribute. If the buffer isn't large enough
// it is reallocated to a bigger size (if possible).
//
if ( VerifyBufferSize( lpByte,
lpNdsBuffer->dwSyntaxAvailableBytes,
lpAttributeInfos[iter2].dwSyntaxId,
lpAttributeInfos[iter2].dwNumberOfValues,
&LengthOfValueStructs ) != NO_ERROR )
{
if ( AllocateOrIncreaseSyntaxBuffer( lpNdsBuffer ) != NO_ERROR )
{
#if DBG
KdPrint(( "NDS32: IndexSearchObjectReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
}
//
// Parse the raw data buffer by mapping the network structures to
// the NDS Syntax structures we define in NdsSntx.h. Then move the
// pointer used to walk the raw data buffer past the ASN.1 Values.
//
lpByte += ParseASN1ValueBlob( lpByte,
lpAttributeInfos[iter2].dwSyntaxId,
lpAttributeInfos[iter2].dwNumberOfValues,
(LPVOID) &lpNdsBuffer->lpSyntaxBuffer[lpNdsBuffer->dwLengthOfSyntaxData] );
lpAttributeInfos[iter2].lpValue =
(LPBYTE) lpNdsBuffer->dwLengthOfSyntaxData;
lpNdsBuffer->dwSyntaxAvailableBytes -= LengthOfValueStructs;
lpNdsBuffer->dwLengthOfSyntaxData += LengthOfValueStructs;
}
}
else
{
lpAttributeInfos = (LPNDS_ATTR_INFO) LocalAlloc(
LPTR,
NumberOfAttributes *
sizeof( NDS_NAME_ONLY )
);
if ( lpAttributeInfos == NULL )
{
#if DBG
KdPrint(("NDS32: IndexSearchObjectReplyBuffer LocalAlloc Failed 0x%.8X\n", GetLastError()));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
for ( iter2 = 0; iter2 < NumberOfAttributes; iter2++ )
{
dwStringLen = *((LPDWORD) lpByte);
lpByte += sizeof(DWORD); // Move past Attribute Name Length
((LPNDS_NAME_ONLY) lpAttributeInfos)[iter2].szName =
(LPWSTR) lpByte;
lpByte += ROUND_UP_COUNT( dwStringLen, ALIGN_DWORD );
}
}
(void) WriteObjectToBuffer( &FixedPortion,
&EndOfVariableData,
newPathStr,
ObjectName,
ClassName,
0, // Don't have this data to write out!
ModificationTime,
SubordinateCount,
NumberOfAttributes,
lpAttributeInfos );
if ( newPathStr )
{
(void) LocalFree( (HLOCAL) newPathStr );
newPathStr = NULL;
}
if ( ObjectName )
{
(void) LocalFree( (HLOCAL) ObjectName );
ObjectName = NULL;
}
lpNdsBuffer->dwNumberOfIndexEntries++;
lpNdsBuffer->dwLengthOfIndexData += sizeof( NDS_CLASS_DEF );
lpNdsBuffer->dwIndexAvailableBytes -= sizeof( NDS_CLASS_DEF );
}
//
// If the syntax buffer was used for the index, we need to convert
// offset values to pointers
//
if ( lpNdsBuffer->dwReplyInformationType == NDS_INFO_ATTR_NAMES_VALUES )
{
for ( iter = 0; iter < lpNdsBuffer->dwNumberOfIndexEntries; iter++ )
{
LPNDS_ATTR_INFO lpNdsAttr = (LPNDS_ATTR_INFO)
lpReplyIndex[iter].lpAttribute;
for ( iter2 = 0;
iter2 < lpReplyIndex[iter].dwNumberOfAttributes;
iter2++ )
{
lpNdsAttr[iter2].lpValue += (DWORD_PTR) lpNdsBuffer->lpSyntaxBuffer;
}
}
}
#if DBG
if ( lpNdsBuffer->dwLengthOfIndexData > lpNdsBuffer->dwIndexBufferSize )
{
KdPrint(( "ASSERT in NDS32: IndexSearchObjectReplyBuffer\n" ));
KdPrint(( " lpNdsBuffer->dwLengthOfIndexData >\n" ));
KdPrint(( " lpNdsBuffer->dwIndexBufferSize\n" ));
ASSERT( FALSE );
}
#endif
return NO_ERROR;
}
DWORD
SizeOfASN1Structure(
LPBYTE * lppRawBuffer,
DWORD dwSyntaxId )
{
DWORD dwSize = 0;
DWORD numFields = 0;
DWORD StringLen = 0;
DWORD dwBlobLength = 0;
LPBYTE lpBlobBeginning = NULL;
LPBYTE lpRawBuffer = *lppRawBuffer;
switch ( dwSyntaxId )
{
case NDS_SYNTAX_ID_1 :
dwSize = sizeof(ASN1_TYPE_1);
break;
case NDS_SYNTAX_ID_2 :
dwSize = sizeof(ASN1_TYPE_2);
break;
case NDS_SYNTAX_ID_3 :
dwSize = sizeof(ASN1_TYPE_3);
break;
case NDS_SYNTAX_ID_4 :
dwSize = sizeof(ASN1_TYPE_4);
break;
case NDS_SYNTAX_ID_5 :
dwSize = sizeof(ASN1_TYPE_5);
break;
case NDS_SYNTAX_ID_6 :
numFields = *(LPDWORD)(lpRawBuffer + sizeof(DWORD));
dwSize = sizeof(ASN1_TYPE_6)*numFields;
break;
case NDS_SYNTAX_ID_7 :
dwSize = sizeof(ASN1_TYPE_7);
break;
case NDS_SYNTAX_ID_8 :
dwSize = sizeof(ASN1_TYPE_8);
break;
case NDS_SYNTAX_ID_9 :
dwSize = sizeof(ASN1_TYPE_9);
break;
case NDS_SYNTAX_ID_10 :
dwSize = sizeof(ASN1_TYPE_10);
break;
case NDS_SYNTAX_ID_11 :
dwSize = sizeof(ASN1_TYPE_11);
break;
case NDS_SYNTAX_ID_12 :
dwSize = sizeof(ASN1_TYPE_12);
break;
case NDS_SYNTAX_ID_13 :
dwSize = sizeof(ASN1_TYPE_13);
break;
case NDS_SYNTAX_ID_14 :
dwSize = sizeof(ASN1_TYPE_14);
break;
case NDS_SYNTAX_ID_15 :
dwSize = sizeof(ASN1_TYPE_15);
break;
case NDS_SYNTAX_ID_16 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
//
// Skip past ServerName
//
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
//
// Skip past ReplicaType
//
lpRawBuffer += sizeof(DWORD);
//
// Skip past ReplicaNumber
//
lpRawBuffer += sizeof(DWORD);
//
// Store address count and move past it
//
numFields = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
dwSize = sizeof(ASN1_TYPE_16) - sizeof(ASN1_TYPE_12) +
( numFields * sizeof(ASN1_TYPE_12) );
*lppRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
case NDS_SYNTAX_ID_17 :
dwSize = sizeof(ASN1_TYPE_17);
break;
case NDS_SYNTAX_ID_18 :
dwSize = sizeof(ASN1_TYPE_18);
break;
case NDS_SYNTAX_ID_19 :
dwSize = sizeof(ASN1_TYPE_19);
break;
case NDS_SYNTAX_ID_20 :
dwSize = sizeof(ASN1_TYPE_20);
break;
case NDS_SYNTAX_ID_21 :
dwSize = sizeof(ASN1_TYPE_21);
break;
case NDS_SYNTAX_ID_22 :
dwSize = sizeof(ASN1_TYPE_22);
break;
case NDS_SYNTAX_ID_23 :
dwSize = sizeof(ASN1_TYPE_23);
break;
case NDS_SYNTAX_ID_24 :
dwSize = sizeof(ASN1_TYPE_24);
break;
case NDS_SYNTAX_ID_25 :
dwSize = sizeof(ASN1_TYPE_25);
break;
case NDS_SYNTAX_ID_26 :
dwSize = sizeof(ASN1_TYPE_26);
break;
case NDS_SYNTAX_ID_27 :
dwSize = sizeof(ASN1_TYPE_27);
break;
default :
KdPrint(( "NDS32: SizeOfASN1Structure() unknown SyntaxId 0x%.8X.\n", dwSyntaxId ));
ASSERT( FALSE );
}
return dwSize;
}
DWORD
ParseASN1ValueBlob(
LPBYTE RawDataBuffer,
DWORD dwSyntaxId,
DWORD dwNumberOfValues,
LPBYTE SyntaxStructure )
{
DWORD iter;
DWORD i;
DWORD length = 0;
LPBYTE lpRawBuffer = RawDataBuffer;
LPBYTE lpSyntaxBuffer = SyntaxStructure;
DWORD StringLen;
DWORD numFields;
DWORD dwBlobLength;
LPBYTE lpBlobBeginning;
for ( iter = 0; iter < dwNumberOfValues; iter++ )
{
switch ( dwSyntaxId )
{
case NDS_SYNTAX_ID_0 :
break;
case NDS_SYNTAX_ID_1 :
case NDS_SYNTAX_ID_2 :
case NDS_SYNTAX_ID_3 :
case NDS_SYNTAX_ID_4 :
case NDS_SYNTAX_ID_5 :
case NDS_SYNTAX_ID_10 :
case NDS_SYNTAX_ID_20 :
StringLen = *(LPDWORD)lpRawBuffer;
length += sizeof(DWORD);
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_1) lpSyntaxBuffer)->DNString =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpSyntaxBuffer += sizeof(ASN1_TYPE_1);
length += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
break;
case NDS_SYNTAX_ID_6 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
numFields = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
for ( iter = 0; iter < numFields; iter++ )
{
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_6) lpSyntaxBuffer)->String =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
if ( (iter+1) < numFields )
{
((LPASN1_TYPE_6) lpSyntaxBuffer)->Next =
(LPASN1_TYPE_6)
(lpSyntaxBuffer +
sizeof(ASN1_TYPE_6) );
}
else
{
((LPASN1_TYPE_6) lpSyntaxBuffer)->Next = NULL;
}
lpSyntaxBuffer += sizeof(ASN1_TYPE_6);
}
length += dwBlobLength + sizeof(DWORD);
lpRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
case NDS_SYNTAX_ID_7 :
StringLen = *(LPDWORD)lpRawBuffer;
length += sizeof(DWORD);
lpRawBuffer += sizeof(DWORD);
ASSERT( StringLen == 1 ); // Booleans are sent as a single
// element DWORD array on the net.
// Although booleans are only the
// first single byte value.
((LPASN1_TYPE_7) lpSyntaxBuffer)->Boolean = *(LPDWORD)lpRawBuffer;
lpSyntaxBuffer += sizeof(ASN1_TYPE_7);
length += StringLen*sizeof(DWORD);
lpRawBuffer += StringLen*sizeof(DWORD);
break;
case NDS_SYNTAX_ID_8 :
case NDS_SYNTAX_ID_22 :
case NDS_SYNTAX_ID_24 :
case NDS_SYNTAX_ID_27 :
StringLen = *(LPDWORD)lpRawBuffer;
length += sizeof(DWORD);
lpRawBuffer += sizeof(DWORD);
ASSERT( StringLen == 4 ); // These DWORD values are all sent
// as a 4 element BYTE array on
// the net.
((LPASN1_TYPE_8) lpSyntaxBuffer)->Integer =
*(LPDWORD)lpRawBuffer;
lpSyntaxBuffer += sizeof(ASN1_TYPE_8);
length += StringLen*sizeof(BYTE);
lpRawBuffer += StringLen*sizeof(BYTE);
break;
case NDS_SYNTAX_ID_9 :
StringLen = *(LPDWORD)lpRawBuffer;
length += sizeof(DWORD);
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_9) lpSyntaxBuffer)->Length = StringLen;
((LPASN1_TYPE_9) lpSyntaxBuffer)->OctetString =
StringLen == 0 ? NULL : lpRawBuffer;
lpSyntaxBuffer += sizeof(ASN1_TYPE_9);
length += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
break;
case NDS_SYNTAX_ID_11 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_11) lpSyntaxBuffer)->TelephoneNumber =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
((LPASN1_TYPE_11) lpSyntaxBuffer)->NumberOfBits =
*(LPDWORD)lpRawBuffer;
if ( ((LPASN1_TYPE_11) lpSyntaxBuffer)->NumberOfBits )
{
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_11) lpSyntaxBuffer)->Parameters = lpRawBuffer;
}
else
{
((LPASN1_TYPE_11) lpSyntaxBuffer)->Parameters = NULL;
}
lpSyntaxBuffer += sizeof(ASN1_TYPE_11);
length += dwBlobLength + sizeof(DWORD);
lpRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
case NDS_SYNTAX_ID_12 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_12) lpSyntaxBuffer)->AddressType =
*(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
StringLen = *(LPDWORD)lpRawBuffer;
((LPASN1_TYPE_12) lpSyntaxBuffer)->AddressLength = StringLen;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_12) lpSyntaxBuffer)->Address =
StringLen == 0 ? NULL : lpRawBuffer;
lpSyntaxBuffer += sizeof(ASN1_TYPE_12);
length += dwBlobLength + sizeof(DWORD);
lpRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
case NDS_SYNTAX_ID_13 :
#if DBG
KdPrint(( "NDS32: ParseASN1ValueBlob() - Don't know how to parse SyntaxId 0x%.8X. Get a sniff and give it to GlennC.\n", dwSyntaxId ));
ASSERT( FALSE );
#endif
break;
case NDS_SYNTAX_ID_14 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_14) lpSyntaxBuffer)->Type =
*(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_14) lpSyntaxBuffer)->Address =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpSyntaxBuffer += sizeof(ASN1_TYPE_14);
length += dwBlobLength + sizeof(DWORD);
lpRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
case NDS_SYNTAX_ID_15 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_15) lpSyntaxBuffer)->Type =
*(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_15) lpSyntaxBuffer)->VolumeName =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_15) lpSyntaxBuffer)->Path =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpSyntaxBuffer += sizeof(ASN1_TYPE_15);
length += dwBlobLength + sizeof(DWORD);
lpRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
case NDS_SYNTAX_ID_16 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_16) lpSyntaxBuffer)->ServerName =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
((LPASN1_TYPE_16) lpSyntaxBuffer)->ReplicaType =
*(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_16) lpSyntaxBuffer)->ReplicaNumber =
*(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_16) lpSyntaxBuffer)->Count =
*(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
for ( i=0; i < ((LPASN1_TYPE_16) lpSyntaxBuffer)->Count; i++ )
{
((LPASN1_TYPE_16) lpSyntaxBuffer)->ReplicaAddressHint[i].AddressType = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
StringLen = *(LPDWORD)lpRawBuffer;
((LPASN1_TYPE_16) lpSyntaxBuffer)->ReplicaAddressHint[i].AddressLength = StringLen;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_16) lpSyntaxBuffer)->ReplicaAddressHint[i].Address = StringLen == 0 ? NULL : lpRawBuffer;
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
}
lpSyntaxBuffer += sizeof(ASN1_TYPE_16) -
sizeof(ASN1_TYPE_12) +
( ((LPASN1_TYPE_16) lpSyntaxBuffer)->Count*
sizeof(ASN1_TYPE_12) );
length += dwBlobLength + sizeof(DWORD);
lpRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
case NDS_SYNTAX_ID_17 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_17) lpSyntaxBuffer)->ProtectedAttrName =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_17) lpSyntaxBuffer)->SubjectName =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
((LPASN1_TYPE_17) lpSyntaxBuffer)->Privileges =
*(LPDWORD)lpRawBuffer;
lpSyntaxBuffer += sizeof(ASN1_TYPE_17);
length += dwBlobLength + sizeof(DWORD);
lpRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
case NDS_SYNTAX_ID_18 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
numFields = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
for ( i = 0; i < numFields; i++ )
{
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_18) lpSyntaxBuffer)->PostalAddress[i] =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
}
lpSyntaxBuffer += sizeof(ASN1_TYPE_18);
length += dwBlobLength + sizeof(DWORD);
lpRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
case NDS_SYNTAX_ID_19 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_19) lpSyntaxBuffer)->WholeSeconds =
*(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_19) lpSyntaxBuffer)->EventID =
*(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
lpSyntaxBuffer += sizeof(ASN1_TYPE_19);
length += dwBlobLength + sizeof(DWORD);
lpRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
case NDS_SYNTAX_ID_21 :
((LPASN1_TYPE_21) lpSyntaxBuffer)->Length =
*(LPDWORD)lpRawBuffer;
lpSyntaxBuffer += sizeof(ASN1_TYPE_21);
length += sizeof(DWORD);
lpRawBuffer += sizeof(DWORD);
break;
case NDS_SYNTAX_ID_23 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_23) lpSyntaxBuffer)->RemoteID =
*(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_23) lpSyntaxBuffer)->ObjectName =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
lpSyntaxBuffer += sizeof(ASN1_TYPE_23);
length += dwBlobLength + sizeof(DWORD);
lpRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
case NDS_SYNTAX_ID_25 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_25) lpSyntaxBuffer)->Level =
*(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_25) lpSyntaxBuffer)->Interval =
*(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_25) lpSyntaxBuffer)->ObjectName =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
lpSyntaxBuffer += sizeof(ASN1_TYPE_25);
length += dwBlobLength + sizeof(DWORD);
lpRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
case NDS_SYNTAX_ID_26 :
lpBlobBeginning = lpRawBuffer;
dwBlobLength = *(LPDWORD)lpRawBuffer*sizeof(BYTE);
dwBlobLength = ROUND_UP_COUNT( dwBlobLength, ALIGN_DWORD );
lpRawBuffer += sizeof(DWORD);
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
((LPASN1_TYPE_26) lpSyntaxBuffer)->ObjectName =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
((LPASN1_TYPE_26) lpSyntaxBuffer)->Amount =
*(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
lpSyntaxBuffer += sizeof(ASN1_TYPE_26);
length += dwBlobLength + sizeof(DWORD);
lpRawBuffer = lpBlobBeginning + dwBlobLength + sizeof(DWORD);
break;
default :
#if DBG
KdPrint(( "NDS32: ParseASN1ValueBlob() unknown SyntaxId 0x%.8X.\n", dwSyntaxId ));
ASSERT( FALSE );
#endif
return 0;
}
}
return length;
}
DWORD
ParseStringListBlob(
LPBYTE RawDataBuffer,
DWORD dwNumberOfStrings,
LPBYTE SyntaxStructure )
{
DWORD iter;
DWORD length = 0;
LPBYTE lpRawBuffer = RawDataBuffer;
LPBYTE lpSyntaxBuffer = SyntaxStructure;
DWORD StringLen;
for ( iter = 0; iter < dwNumberOfStrings; iter++ )
{
StringLen = *(LPDWORD)lpRawBuffer;
lpRawBuffer += sizeof(DWORD);
length += sizeof(DWORD);
((LPASN1_TYPE_6) lpSyntaxBuffer)->String =
StringLen == 0 ? NULL : (LPWSTR) lpRawBuffer;
lpRawBuffer += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
length += ROUND_UP_COUNT( StringLen, ALIGN_DWORD );
if ( (iter+1) < dwNumberOfStrings )
{
((LPASN1_TYPE_6) lpSyntaxBuffer)->Next = (LPASN1_TYPE_6)
(lpSyntaxBuffer +
sizeof(ASN1_TYPE_6) );
}
else
{
((LPASN1_TYPE_6) lpSyntaxBuffer)->Next = NULL;
}
lpSyntaxBuffer += sizeof(ASN1_TYPE_6);
}
return length;
}
WORD
ParseNdsUncPath(
IN OUT LPWSTR * lpszResult,
IN LPWSTR szObjectPathName,
IN DWORD flag )
{
unsigned short length = 2;
unsigned short totalLength = (USHORT) wcslen( szObjectPathName );
if ( totalLength < 2 )
return 0;
//
// Get length to indicate the character in the string that indicates the
// "\" in between the tree name and the rest of the UNC path.
//
// Example: \\<tree name>\<path to object>[\|.]<object>
// ^
// |
//
while ( length < totalLength && szObjectPathName[length] != L'\\' )
{
length++;
}
if ( flag == PARSE_NDS_GET_TREE_NAME )
{
*lpszResult = (LPWSTR) ( szObjectPathName + 2 );
return ( length - 2 ) * sizeof(WCHAR); // Take off 2 for the two \\'s
}
if ( flag == PARSE_NDS_GET_PATH_NAME && length == totalLength )
{
*lpszResult = szObjectPathName;
return 0;
}
if ( flag == PARSE_NDS_GET_PATH_NAME )
{
*lpszResult = szObjectPathName + length + 1;
return ( totalLength - length - 1 ) * sizeof(WCHAR);
}
if ( flag == PARSE_NDS_GET_OBJECT_NAME )
{
unsigned short ObjectNameLength = 0;
*lpszResult = szObjectPathName + length + 1;
length++;
while ( length < totalLength && szObjectPathName[length] != L'.' )
{
length++;
ObjectNameLength++;
}
return ObjectNameLength * sizeof(WCHAR);
}
*lpszResult = szObjectPathName + totalLength - 1;
length = 1;
while ( *lpszResult[0] != L'\\' )
{
*lpszResult--;
length++;
}
*lpszResult++;
length--;
return length * sizeof(WCHAR);
}
DWORD
ReadAttrDef_AllAttrs(
IN HANDLE hTree,
IN DWORD dwInformationType,
OUT HANDLE * lphOperationData )
{
DWORD status;
DWORD nwstatus;
NTSTATUS ntstatus;
LPNDS_BUFFER lpNdsBuffer = NULL;
DWORD dwReplyLength;
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hTree;
DWORD dwIterHandle = NDS_NO_MORE_ITERATIONS;
DWORD dwNumEntries = 0;
DWORD dwCurrNumEntries = 0;
DWORD dwCurrBuffSize = 0;
DWORD dwCopyOffset = 0;
PVOID lpCurrBuff = NULL;
PVOID lpTempBuff = NULL;
DWORD dwInfoType = dwInformationType;
*lphOperationData = NULL;
status = NwNdsCreateBuffer( NDS_SCHEMA_READ_ATTR_DEF,
(HANDLE *) &lpNdsBuffer );
if ( status )
{
goto ErrorExit;
}
lpNdsBuffer->lpReplyBuffer = NULL;
lpNdsBuffer->dwReplyBufferSize = 0;
//
// Reasonable guess is that the response buffer needs to be 8K bytes.
//
dwCurrBuffSize = EIGHT_KB;
lpCurrBuff = (PVOID) LocalAlloc( LPTR, dwCurrBuffSize );
//
// Check that the memory allocation was successful.
//
if ( lpCurrBuff == NULL )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_AllAttrs LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
do
{
SendRequest:
ntstatus = FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_READ_ATTR_DEF,
lpCurrBuff,
dwCurrBuffSize,
&dwReplyLength,
"DDDDD",
0, // Version
dwIterHandle, // Initial iteration
dwInformationType,
(DWORD) TRUE, // All attributes indicator
0 ); // Number of attribute names
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_AllAttrs: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
ntstatus = ParseResponse( lpCurrBuff,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_AllAttrs: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( nwstatus )
{
if (nwstatus == NDS_ERR_INSUFFICIENT_BUFFER)
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_AllAttrs - NDS_ERR_INSUFFICIENT_BUFFER - doubling size from %ld\n", dwCurrBuffSize ));
#endif
//
// The buffer was too small, make it twice as big.
//
if ( dwCurrBuffSize <= THIRY_TWO_KB)
{ // NDS_MAX_BUFFER = 0xFC00
dwCurrBuffSize *= 2;
if (dwCurrBuffSize > NDS_MAX_BUFFER)
dwCurrBuffSize = NDS_MAX_BUFFER;
lpTempBuff = (PVOID) LocalAlloc(LPTR, dwCurrBuffSize);
if (lpTempBuff)
{
(void) LocalFree((HLOCAL) lpCurrBuff);
lpCurrBuff = lpTempBuff;
lpTempBuff = NULL;
// Error cancels iteration, so reset any previously read responses and start over
dwIterHandle = NDS_NO_MORE_ITERATIONS;
if (lpNdsBuffer->lpReplyBuffer)
{
(void) LocalFree((HLOCAL) lpNdsBuffer->lpReplyBuffer);
lpNdsBuffer->lpReplyBuffer = NULL;
lpNdsBuffer->dwReplyBufferSize = 0;
dwNumEntries = 0;
}
goto SendRequest;
}
#if DBG
else {
KdPrint(( "NDS32: ReadAttrDef_AllAttrs - Buffer ReAlloc failed to increase to %ld\n", dwCurrBuffSize ));
}
#endif
}
}
#if DBG
KdPrint(( "NDS32: ReadAttrDef_AllAttrs - NetWare error 0x%.8X.\n", nwstatus ));
#endif
SetLastError( MapNetwareErrorCode( nwstatus ) );
status = nwstatus;
goto ErrorExit;
}
ntstatus = ParseResponse( (BYTE *) lpCurrBuff,
dwReplyLength,
"G_DDD",
sizeof(DWORD),
&dwIterHandle,
&dwInfoType,
&dwCurrNumEntries );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_AllAttrs: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( lpNdsBuffer->lpReplyBuffer == NULL) // first time through
{
dwCopyOffset = 0; // we want the entire buffer the first time
lpTempBuff = (PVOID) LocalAlloc( LPTR, dwCurrBuffSize ); // Allocate new reply buffer
}
else
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_AllAttrs - subsequent iteration, ReplyBuffer now %ld\n", lpNdsBuffer->dwReplyBufferSize + dwCurrBuffSize - dwCopyOffset ));
#endif
dwCopyOffset = 4 * sizeof(DWORD); // skip the response code, iteration handle, etc. on subsequent iterations
lpTempBuff = (PVOID) LocalAlloc (LPTR, lpNdsBuffer->dwReplyBufferSize + dwCurrBuffSize - dwCopyOffset);
// grow reply buffer to hold additional data
if (lpTempBuff)
{
RtlCopyMemory( lpTempBuff, lpNdsBuffer->lpReplyBuffer, lpNdsBuffer->dwReplyBufferSize);
(void) LocalFree((HLOCAL) lpNdsBuffer->lpReplyBuffer);
}
}
if (lpTempBuff == NULL)
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_AllAttrs LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
RtlCopyMemory( (LPBYTE) ((LPBYTE) (lpTempBuff) + lpNdsBuffer->dwReplyBufferSize),
(LPBYTE) ((LPBYTE) (lpCurrBuff) + dwCopyOffset),
(dwCurrBuffSize - dwCopyOffset) );
lpNdsBuffer->lpReplyBuffer = lpTempBuff;
lpNdsBuffer->dwReplyBufferSize += (dwCurrBuffSize - dwCopyOffset);
dwNumEntries += dwCurrNumEntries;
RtlZeroMemory(lpCurrBuff, dwCurrBuffSize);
} while ( dwIterHandle != NDS_NO_MORE_ITERATIONS );
lpNdsBuffer->dwNumberOfReplyEntries = dwNumEntries;
lpNdsBuffer->dwReplyInformationType = dwInfoType;
*lphOperationData = lpNdsBuffer;
(void) LocalFree( (HLOCAL) lpCurrBuff );
return NO_ERROR;
ErrorExit :
if ( lpCurrBuff )
{
(void) LocalFree( (HLOCAL) lpCurrBuff );
lpCurrBuff = NULL;
}
if ( lpNdsBuffer )
{
(void) NwNdsFreeBuffer( (HANDLE) lpNdsBuffer );
lpNdsBuffer = NULL;
}
return status;
}
DWORD
ReadAttrDef_SomeAttrs(
IN HANDLE hTree,
IN DWORD dwInformationType,
IN OUT HANDLE * lphOperationData )
{
DWORD status;
DWORD nwstatus;
NTSTATUS ntstatus;
LPNDS_BUFFER lpNdsBuffer = (LPNDS_BUFFER) *lphOperationData;
DWORD dwReplyLength;
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hTree;
DWORD dwIterHandle = NDS_NO_MORE_ITERATIONS;
DWORD dwInfoType = dwInformationType;
DWORD dwNumEntries = 0;
DWORD dwCurrNumEntries = 0;
DWORD dwCurrBuffSize = 0;
DWORD dwCopyOffset = 0;
PVOID lpCurrBuff = NULL;
PVOID lpTempBuff = NULL;
if ( lpNdsBuffer->dwOperation != NDS_SCHEMA_READ_ATTR_DEF )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Check to see if this buffer has already been used for a read reply.
//
if ( lpNdsBuffer->lpReplyBuffer )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
lpNdsBuffer->dwReplyBufferSize = 0;
//
// Reasonable guess is that the response buffer needs to be 8K bytes.
//
dwCurrBuffSize = EIGHT_KB;
lpCurrBuff = (PVOID) LocalAlloc( LPTR, dwCurrBuffSize );
//
// Check that the memory allocation was successful.
//
if ( lpCurrBuff == NULL )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
do
{
SendRequest:
ntstatus = FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_READ_ATTR_DEF,
lpCurrBuff,
dwCurrBuffSize,
&dwReplyLength,
"DDDDDr",
0, // Version
dwIterHandle, // Initial iteration
dwInformationType,
(DWORD) FALSE, // All attributes indicator
lpNdsBuffer->dwNumberOfRequestEntries,
lpNdsBuffer->lpRequestBuffer,
(WORD)lpNdsBuffer->dwLengthOfRequestData );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
ntstatus = ParseResponse( lpCurrBuff,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( nwstatus )
{
if (nwstatus == NDS_ERR_INSUFFICIENT_BUFFER)
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs - NDS_ERR_INSUFFICIENT_BUFFER - doubling size from %ld\n", dwCurrBuffSize ));
#endif
//
// The buffer was too small, make it twice as big.
//
if ( dwCurrBuffSize <= THIRY_TWO_KB)
{ // NDS_MAX_BUFFER = 0xFC00
dwCurrBuffSize *= 2;
if (dwCurrBuffSize > NDS_MAX_BUFFER)
dwCurrBuffSize = NDS_MAX_BUFFER;
lpTempBuff = (PVOID) LocalAlloc(LPTR, dwCurrBuffSize);
if (lpTempBuff)
{
(void) LocalFree((HLOCAL) lpCurrBuff);
lpCurrBuff = lpTempBuff;
lpTempBuff = NULL;
// Error cancels iteration, so reset any previously read responses and start over
dwIterHandle = NDS_NO_MORE_ITERATIONS;
if (lpNdsBuffer->lpReplyBuffer)
{
(void) LocalFree((HLOCAL) lpNdsBuffer->lpReplyBuffer);
lpNdsBuffer->lpReplyBuffer = NULL;
lpNdsBuffer->dwReplyBufferSize = 0;
dwNumEntries = 0;
}
goto SendRequest;
}
#if DBG
else {
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs - Buffer ReAlloc failed to increase to %ld\n", dwCurrBuffSize ));
}
#endif
}
}
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs - NetWare error 0x%.8X.\n", nwstatus ));
#endif
SetLastError( MapNetwareErrorCode( nwstatus ) );
status = nwstatus;
goto ErrorExit;
}
ntstatus = ParseResponse( (BYTE *) lpCurrBuff,
dwReplyLength,
"G_DDD",
sizeof(DWORD),
&dwIterHandle,
&dwInfoType,
&dwCurrNumEntries );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( lpNdsBuffer->lpReplyBuffer == NULL) // first time through
{
dwCopyOffset = 0; // we want the entire buffer the first time
lpTempBuff = (PVOID) LocalAlloc( LPTR, dwCurrBuffSize ); // Allocate new reply buffer
}
else
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs - subsequent iteration, ReplyBuffer now %ld\n", lpNdsBuffer->dwReplyBufferSize + dwCurrBuffSize - dwCopyOffset ));
#endif
dwCopyOffset = 4 * sizeof(DWORD); // skip the response code, iteration handle, etc. on subsequent iterations
lpTempBuff = (PVOID) LocalAlloc (LPTR, lpNdsBuffer->dwReplyBufferSize + dwCurrBuffSize - dwCopyOffset);
// grow reply buffer to hold additional data
if (lpTempBuff)
{
RtlCopyMemory( lpTempBuff, lpNdsBuffer->lpReplyBuffer, lpNdsBuffer->dwReplyBufferSize);
(void) LocalFree((HLOCAL) lpNdsBuffer->lpReplyBuffer);
}
}
if (lpTempBuff == NULL)
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
RtlCopyMemory( (LPBYTE) ((LPBYTE) (lpTempBuff) + lpNdsBuffer->dwReplyBufferSize),
(LPBYTE) ((LPBYTE) (lpCurrBuff) + dwCopyOffset),
(dwCurrBuffSize - dwCopyOffset) );
lpNdsBuffer->lpReplyBuffer = lpTempBuff;
lpNdsBuffer->dwReplyBufferSize += (dwCurrBuffSize - dwCopyOffset);
dwNumEntries += dwCurrNumEntries;
RtlZeroMemory(lpCurrBuff, dwCurrBuffSize);
} while ( dwIterHandle != NDS_NO_MORE_ITERATIONS );
lpNdsBuffer->dwNumberOfReplyEntries = dwNumEntries;
lpNdsBuffer->dwReplyInformationType = dwInfoType;
(void) LocalFree( (HLOCAL) lpCurrBuff );
return NO_ERROR;
ErrorExit :
if ( lpCurrBuff )
{
(void) LocalFree( (HLOCAL) lpCurrBuff );
lpCurrBuff = NULL;
}
if ( lpNdsBuffer->lpReplyBuffer )
{
(void) LocalFree( (HLOCAL) lpNdsBuffer->lpReplyBuffer );
lpNdsBuffer->lpReplyBuffer = NULL;
lpNdsBuffer->dwReplyBufferSize = 0;
}
return status;
}
DWORD
ReadClassDef_AllClasses(
IN HANDLE hTree,
IN DWORD dwInformationType,
OUT HANDLE * lphOperationData )
{
DWORD status;
DWORD nwstatus;
NTSTATUS ntstatus;
LPNDS_BUFFER lpNdsBuffer = NULL;
DWORD dwReplyLength;
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hTree;
DWORD dwIterHandle = NDS_NO_MORE_ITERATIONS;
DWORD dwNumEntries = 0;
DWORD dwCurrNumEntries = 0;
DWORD dwCurrBuffSize = 0;
DWORD dwCopyOffset = 0;
PVOID lpCurrBuff = NULL;
PVOID lpTempBuff = NULL;
DWORD dwInfoType = dwInformationType;
*lphOperationData = NULL;
status = NwNdsCreateBuffer( NDS_SCHEMA_READ_CLASS_DEF,
(HANDLE *) &lpNdsBuffer );
if ( status )
{
goto ErrorExit;
}
lpNdsBuffer->lpReplyBuffer = NULL;
lpNdsBuffer->dwReplyBufferSize = 0;
//
// Reasonable guess is that the response buffer needs to be 16K bytes.
//
dwCurrBuffSize = SIXTEEN_KB;
lpCurrBuff = (PVOID) LocalAlloc( LPTR, dwCurrBuffSize );
//
// Check that the memory allocation was successful.
//
if ( lpCurrBuff == NULL )
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_AllClasses LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
do
{
SendRequest:
ntstatus = FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_READ_CLASS_DEF,
lpCurrBuff,
dwCurrBuffSize,
&dwReplyLength,
"DDDDD",
0, // Version
dwIterHandle, // Initial iteration
dwInformationType,
(DWORD) TRUE, // All attributes indicator
0 ); // Number of attribute names
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_AllClasses: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
ntstatus = ParseResponse( lpCurrBuff,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_AllClasses: The read response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( nwstatus )
{
if (nwstatus == NDS_ERR_INSUFFICIENT_BUFFER)
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_AllClasses - NDS_ERR_INSUFFICIENT_BUFFER - doubling size from %ld\n", dwCurrBuffSize ));
#endif
//
// The buffer was too small, make it twice as big.
//
if ( dwCurrBuffSize <= THIRY_TWO_KB)
{ // NDS_MAX_BUFFER = 0xFC00
dwCurrBuffSize *= 2;
if (dwCurrBuffSize > NDS_MAX_BUFFER)
dwCurrBuffSize = NDS_MAX_BUFFER;
lpTempBuff = (PVOID) LocalAlloc(LPTR, dwCurrBuffSize);
if (lpTempBuff)
{
(void) LocalFree((HLOCAL) lpCurrBuff);
lpCurrBuff = lpTempBuff;
lpTempBuff = NULL;
// Error cancels iteration, so reset any previously read responses and start over
dwIterHandle = NDS_NO_MORE_ITERATIONS;
if (lpNdsBuffer->lpReplyBuffer)
{
(void) LocalFree((HLOCAL) lpNdsBuffer->lpReplyBuffer);
lpNdsBuffer->lpReplyBuffer = NULL;
lpNdsBuffer->dwReplyBufferSize = 0;
dwNumEntries = 0;
}
goto SendRequest;
}
#if DBG
else {
KdPrint(( "NDS32: ReadClassDef_AllClasses - Buffer ReAlloc failed to increase to %ld\n", dwCurrBuffSize ));
}
#endif
}
}
#if DBG
KdPrint(( "NDS32: ReadClassDef_AllClasses - NetWare error 0x%.8X.\n", nwstatus ));
#endif
SetLastError( MapNetwareErrorCode( nwstatus ) );
status = nwstatus;
goto ErrorExit;
}
ntstatus = ParseResponse( (BYTE *) lpCurrBuff,
dwReplyLength,
"G_DDD",
sizeof(DWORD),
&dwIterHandle,
&dwInfoType,
&dwCurrNumEntries );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_AllClasses: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( lpNdsBuffer->lpReplyBuffer == NULL) // first time through
{
dwCopyOffset = 0; // we want the entire buffer the first time
lpTempBuff = (PVOID) LocalAlloc( LPTR, dwCurrBuffSize ); // Allocate new reply buffer
}
else
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_AllClasses - subsequent iteration, ReplyBuffer now %ld\n", lpNdsBuffer->dwReplyBufferSize + dwCurrBuffSize - dwCopyOffset ));
#endif
dwCopyOffset = 4 * sizeof(DWORD); // skip the response code, iteration handle, etc. on subsequent iterations
lpTempBuff = (PVOID) LocalAlloc (LPTR, lpNdsBuffer->dwReplyBufferSize + dwCurrBuffSize - dwCopyOffset);
// grow reply buffer to hold additional data
if (lpTempBuff)
{
RtlCopyMemory( lpTempBuff, lpNdsBuffer->lpReplyBuffer, lpNdsBuffer->dwReplyBufferSize);
(void) LocalFree((HLOCAL) lpNdsBuffer->lpReplyBuffer);
}
}
if (lpTempBuff == NULL)
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_AllClasses LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
RtlCopyMemory( (LPBYTE) ((LPBYTE) (lpTempBuff) + lpNdsBuffer->dwReplyBufferSize),
(LPBYTE) ((LPBYTE) (lpCurrBuff) + dwCopyOffset),
(dwCurrBuffSize - dwCopyOffset) );
lpNdsBuffer->lpReplyBuffer = lpTempBuff;
lpNdsBuffer->dwReplyBufferSize += (dwCurrBuffSize - dwCopyOffset);
dwNumEntries += dwCurrNumEntries;
RtlZeroMemory(lpCurrBuff, dwCurrBuffSize);
} while ( dwIterHandle != NDS_NO_MORE_ITERATIONS );
lpNdsBuffer->dwNumberOfReplyEntries = dwNumEntries;
lpNdsBuffer->dwReplyInformationType = dwInfoType;
*lphOperationData = lpNdsBuffer;
(void) LocalFree( (HLOCAL) lpCurrBuff );
return NO_ERROR;
ErrorExit :
if ( lpCurrBuff )
{
(void) LocalFree( (HLOCAL) lpCurrBuff );
lpCurrBuff = NULL;
}
if ( lpNdsBuffer )
{
(void) NwNdsFreeBuffer( (HANDLE) lpNdsBuffer );
lpNdsBuffer = NULL;
}
return status;
}
DWORD
ReadClassDef_SomeClasses(
IN HANDLE hTree,
IN DWORD dwInformationType,
IN OUT HANDLE * lphOperationData )
{
DWORD status;
DWORD nwstatus;
NTSTATUS ntstatus;
LPNDS_BUFFER lpNdsBuffer = (LPNDS_BUFFER) *lphOperationData;
DWORD dwReplyLength;
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hTree;
DWORD dwIterHandle = NDS_NO_MORE_ITERATIONS;
DWORD dwInfoType = dwInformationType;
DWORD dwNumEntries = 0;
DWORD dwCurrNumEntries = 0;
DWORD dwCurrBuffSize = 0;
DWORD dwCopyOffset = 0;
PVOID lpCurrBuff = NULL;
PVOID lpTempBuff = NULL;
if ( lpNdsBuffer->dwOperation != NDS_SCHEMA_READ_CLASS_DEF )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Check to see if this buffer has already been used for a read reply.
//
if ( lpNdsBuffer->lpReplyBuffer )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
lpNdsBuffer->dwReplyBufferSize = 0;
//
// Reasonable guess is that the response buffer needs to be 16K bytes.
//
dwCurrBuffSize = SIXTEEN_KB;
lpCurrBuff = (PVOID) LocalAlloc( LPTR, dwCurrBuffSize );
//
// Check that the memory allocation was successful.
//
if ( lpCurrBuff == NULL )
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_SomeClasses LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
do
{
SendRequest:
ntstatus = FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_READ_CLASS_DEF,
lpCurrBuff,
dwCurrBuffSize,
&dwReplyLength,
"DDDDDr",
0, // Version
dwIterHandle, // Initial iteration
dwInformationType,
(DWORD) FALSE, // All attributes indicator
lpNdsBuffer->dwNumberOfRequestEntries,
lpNdsBuffer->lpRequestBuffer,
(WORD)lpNdsBuffer->dwLengthOfRequestData );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_SomeClasses: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
ntstatus = ParseResponse( lpCurrBuff,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_SomeClasses: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( nwstatus )
{
if (nwstatus == NDS_ERR_INSUFFICIENT_BUFFER)
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_SomeClasses - NDS_ERR_INSUFFICIENT_BUFFER - doubling size from %ld\n", dwCurrBuffSize ));
#endif
//
// The buffer was too small, make it twice as big.
//
if ( dwCurrBuffSize <= THIRY_TWO_KB)
{ // NDS_MAX_BUFFER = 0xFC00
dwCurrBuffSize *= 2;
if (dwCurrBuffSize > NDS_MAX_BUFFER)
dwCurrBuffSize = NDS_MAX_BUFFER;
lpTempBuff = (PVOID) LocalAlloc(LPTR, dwCurrBuffSize);
if (lpTempBuff)
{
(void) LocalFree((HLOCAL) lpCurrBuff);
lpCurrBuff = lpTempBuff;
lpTempBuff = NULL;
// Error cancels iteration, so reset any previously read responses and start over
dwIterHandle = NDS_NO_MORE_ITERATIONS;
if (lpNdsBuffer->lpReplyBuffer)
{
(void) LocalFree((HLOCAL) lpNdsBuffer->lpReplyBuffer);
lpNdsBuffer->lpReplyBuffer = NULL;
lpNdsBuffer->dwReplyBufferSize = 0;
dwNumEntries = 0;
}
goto SendRequest;
}
#if DBG
else {
KdPrint(( "NDS32: ReadClassDef_SomeClasses - Buffer ReAlloc failed to increase to %ld\n", dwCurrBuffSize ));
}
#endif
}
}
#if DBG
KdPrint(( "NDS32: ReadClassDef_SomeClasses - NetWare error 0x%.8X.\n", nwstatus ));
#endif
SetLastError( MapNetwareErrorCode( nwstatus ) );
status = nwstatus;
goto ErrorExit;
}
ntstatus = ParseResponse( (BYTE *) lpCurrBuff,
dwReplyLength,
"G_DDD",
sizeof(DWORD),
&dwIterHandle,
&dwInfoType,
&dwCurrNumEntries );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_SomeClasses: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( lpNdsBuffer->lpReplyBuffer == NULL) // first time through
{
dwCopyOffset = 0; // we want the entire buffer the first time
lpTempBuff = (PVOID) LocalAlloc( LPTR, dwCurrBuffSize ); // Allocate new reply buffer
}
else
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_SomeClasses - subsequent iteration, ReplyBuffer now %ld\n", lpNdsBuffer->dwReplyBufferSize + dwCurrBuffSize - dwCopyOffset ));
#endif
dwCopyOffset = 4 * sizeof(DWORD); // skip the response code, iteration handle, etc. on subsequent iterations
lpTempBuff = (PVOID) LocalAlloc (LPTR, lpNdsBuffer->dwReplyBufferSize + dwCurrBuffSize - dwCopyOffset);
// grow reply buffer to hold additional data
if (lpTempBuff)
{
RtlCopyMemory( lpTempBuff, lpNdsBuffer->lpReplyBuffer, lpNdsBuffer->dwReplyBufferSize);
(void) LocalFree((HLOCAL) lpNdsBuffer->lpReplyBuffer);
}
}
if (lpTempBuff == NULL)
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_SomeClasses LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
RtlCopyMemory( (LPBYTE) ((LPBYTE) (lpTempBuff) + lpNdsBuffer->dwReplyBufferSize),
(LPBYTE) ((LPBYTE) (lpCurrBuff) + dwCopyOffset),
(dwCurrBuffSize - dwCopyOffset) );
lpNdsBuffer->lpReplyBuffer = lpTempBuff;
lpNdsBuffer->dwReplyBufferSize += (dwCurrBuffSize - dwCopyOffset);
dwNumEntries += dwCurrNumEntries;
RtlZeroMemory(lpCurrBuff, dwCurrBuffSize);
} while ( dwIterHandle != NDS_NO_MORE_ITERATIONS );
lpNdsBuffer->dwNumberOfReplyEntries = dwNumEntries;
lpNdsBuffer->dwReplyInformationType = dwInfoType;
(void) LocalFree( (HLOCAL) lpCurrBuff );
return NO_ERROR;
ErrorExit :
if ( lpCurrBuff )
{
(void) LocalFree( (HLOCAL) lpCurrBuff );
lpCurrBuff = NULL;
}
if ( lpNdsBuffer->lpReplyBuffer )
{
(void) LocalFree( (HLOCAL) lpNdsBuffer->lpReplyBuffer );
lpNdsBuffer->lpReplyBuffer = NULL;
lpNdsBuffer->dwReplyBufferSize = 0;
}
return status;
}
DWORD
ReadObject_AllAttrs(
IN HANDLE hObject,
IN DWORD dwInformationType,
OUT HANDLE * lphOperationData )
{
DWORD status;
DWORD nwstatus;
NTSTATUS ntstatus;
LPNDS_BUFFER lpNdsBuffer = NULL;
DWORD dwReplyLength;
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hObject;
DWORD dwIterHandle = NDS_NO_MORE_ITERATIONS;
DWORD dwNumEntries = 0;
DWORD dwCurrNumEntries = 0;
DWORD dwCurrBuffSize = 0;
DWORD dwCopyOffset = 0;
PVOID lpCurrBuff = NULL;
PVOID lpTempBuff = NULL;
DWORD dwInfoType = dwInformationType;
if ( lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
status = NwNdsCreateBuffer( NDS_OBJECT_READ,
(HANDLE *) &lpNdsBuffer );
if ( status )
{
goto ErrorExit;
}
lpNdsBuffer->lpReplyBuffer = NULL;
lpNdsBuffer->dwReplyBufferSize = 0;
//
// We're asking for all attribute values, so let's start with max buffer to avoid iterations.
//
dwCurrBuffSize = NDS_MAX_BUFFER;
lpCurrBuff = (PVOID) LocalAlloc( LPTR, dwCurrBuffSize );
//
// Check that the memory allocation was successful.
//
if ( lpCurrBuff == NULL )
{
#if DBG
KdPrint(( "NDS32: ReadObject_AllAttrs LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
do
{
ntstatus = FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_READ_OBJECT,
lpCurrBuff,
dwCurrBuffSize,
&dwReplyLength,
"DDDDDD",
0, // Version
dwIterHandle, // Initial iteration
lpNdsObject->ObjectId, // Id of the object
dwInformationType,
(DWORD) TRUE, // All attributes indicator
0 ); // Number of attribute names
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadObject_AllAttrs: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
ntstatus = ParseResponse( lpCurrBuff,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadObject_AllAttrs: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( nwstatus )
{
#if DBG
KdPrint(( "NDS32: ReadObject_AllAttrs - NetWare error 0x%.8X.\n", nwstatus ));
#endif
SetLastError( MapNetwareErrorCode( nwstatus ) );
status = nwstatus;
goto ErrorExit;
}
ntstatus = ParseResponse( (BYTE *) lpCurrBuff,
dwReplyLength,
"G_DDD",
sizeof(DWORD),
&dwIterHandle,
&dwInfoType,
&dwCurrNumEntries );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadObject_AllAttrs: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( lpNdsBuffer->lpReplyBuffer == NULL) // first time through
{
dwCopyOffset = 0; // we want the entire buffer the first time
lpTempBuff = (PVOID) LocalAlloc( LPTR, dwCurrBuffSize ); // Allocate new reply buffer
}
else
{
#if DBG
KdPrint(( "NDS32: ReadObject_AllAttrs - subsequent iteration, ReplyBuffer now %ld\n", lpNdsBuffer->dwReplyBufferSize + dwCurrBuffSize - dwCopyOffset ));
#endif
dwCopyOffset = 4 * sizeof(DWORD); // skip the response code, iteration handle, etc. on subsequent iterations
lpTempBuff = (PVOID) LocalAlloc (LPTR, lpNdsBuffer->dwReplyBufferSize + dwCurrBuffSize - dwCopyOffset);
// grow reply buffer to hold additional data
if (lpTempBuff)
{
RtlCopyMemory( lpTempBuff, lpNdsBuffer->lpReplyBuffer, lpNdsBuffer->dwReplyBufferSize);
(void) LocalFree((HLOCAL) lpNdsBuffer->lpReplyBuffer);
}
}
if (lpTempBuff == NULL)
{
#if DBG
KdPrint(( "NDS32: ReadObject_AllAttrs LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
RtlCopyMemory( (LPBYTE) ((LPBYTE) (lpTempBuff) + lpNdsBuffer->dwReplyBufferSize),
(LPBYTE) ((LPBYTE) (lpCurrBuff) + dwCopyOffset),
(dwCurrBuffSize - dwCopyOffset) );
lpNdsBuffer->lpReplyBuffer = lpTempBuff;
lpNdsBuffer->dwReplyBufferSize += (dwCurrBuffSize - dwCopyOffset);
dwNumEntries += dwCurrNumEntries;
RtlZeroMemory(lpCurrBuff, dwCurrBuffSize);
} while ( dwIterHandle != NDS_NO_MORE_ITERATIONS );
lpNdsBuffer->dwNumberOfReplyEntries = dwNumEntries;
lpNdsBuffer->dwReplyInformationType = dwInfoType;
*lphOperationData = lpNdsBuffer;
(void) LocalFree( (HLOCAL) lpCurrBuff );
return NO_ERROR;
ErrorExit :
if ( lpCurrBuff )
{
(void) LocalFree( (HLOCAL) lpCurrBuff );
lpCurrBuff = NULL;
}
if ( lpNdsBuffer )
{
(void) NwNdsFreeBuffer( (HANDLE) lpNdsBuffer );
lpNdsBuffer = NULL;
}
return status;
}
DWORD
ReadObject_SomeAttrs(
IN HANDLE hObject,
IN DWORD dwInformationType,
IN OUT HANDLE * lphOperationData )
{
DWORD status;
DWORD nwstatus;
NTSTATUS ntstatus;
LPNDS_BUFFER lpNdsBuffer = (LPNDS_BUFFER) *lphOperationData;
DWORD dwReplyLength;
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hObject;
DWORD dwIterHandle = NDS_NO_MORE_ITERATIONS;
DWORD dwInfoType = dwInformationType;
DWORD dwNumEntries = 0;
DWORD dwCurrNumEntries = 0;
DWORD dwCurrBuffSize = 0;
DWORD dwCopyOffset = 0;
PVOID lpCurrBuff = NULL;
PVOID lpTempBuff = NULL;
if ( lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
if ( lpNdsBuffer->dwOperation != NDS_OBJECT_READ )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Check to see if this buffer has already been used for a read reply.
//
if ( lpNdsBuffer->lpReplyBuffer )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
lpNdsBuffer->dwReplyBufferSize = 0;
//
// We may be asking for all values, so let's start with max buffer to avoid iterations.
//
dwCurrBuffSize = NDS_MAX_BUFFER;
lpCurrBuff = (PVOID) LocalAlloc( LPTR, dwCurrBuffSize );
//
// Check that the memory allocation was successful.
//
if ( lpCurrBuff == NULL )
{
#if DBG
KdPrint(( "NDS32: ReadObject_SomeAttrs LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
do
{
ntstatus = FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_READ_OBJECT,
lpCurrBuff,
dwCurrBuffSize,
&dwReplyLength,
"DDDDDDr",
0, // Version
dwIterHandle, // Initial iteration
lpNdsObject->ObjectId, // Id of the object
dwInformationType,
(DWORD) FALSE, // All attributes indicator
lpNdsBuffer->dwNumberOfRequestEntries,
lpNdsBuffer->lpRequestBuffer, // Object info
(WORD)lpNdsBuffer->dwLengthOfRequestData );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadObject_SomeAttrs: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
ntstatus = ParseResponse( (BYTE *) lpCurrBuff,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadObject_SomeAttrs: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( nwstatus )
{
#if DBG
KdPrint(( "NDS32: ReadClassDef_SomeClasses - NetWare error 0x%.8X.\n", nwstatus ));
#endif
SetLastError( MapNetwareErrorCode( nwstatus ) );
status = nwstatus;
goto ErrorExit;
}
ntstatus = ParseResponse( (BYTE *) lpCurrBuff,
dwReplyLength,
"G_DDD",
sizeof(DWORD),
&dwIterHandle,
&dwInfoType,
&dwCurrNumEntries );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadObject_SomeAttrs: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( lpNdsBuffer->lpReplyBuffer == NULL) // first time through
{
dwCopyOffset = 0; // we want the entire buffer the first time
lpTempBuff = (PVOID) LocalAlloc( LPTR, dwCurrBuffSize ); // Allocate new reply buffer
}
else
{
#if DBG
KdPrint(( "NDS32: ReadObject_SomeAttrs - subsequent iteration, ReplyBuffer now %ld\n", lpNdsBuffer->dwReplyBufferSize + dwCurrBuffSize - dwCopyOffset ));
#endif
dwCopyOffset = 4 * sizeof(DWORD); // skip the response code, iteration handle, etc. on subsequent iterations
lpTempBuff = (PVOID) LocalAlloc (LPTR, lpNdsBuffer->dwReplyBufferSize + dwCurrBuffSize - dwCopyOffset);
// grow reply buffer to hold additional data
if (lpTempBuff)
{
RtlCopyMemory( lpTempBuff, lpNdsBuffer->lpReplyBuffer, lpNdsBuffer->dwReplyBufferSize);
(void) LocalFree((HLOCAL) lpNdsBuffer->lpReplyBuffer);
}
}
if (lpTempBuff == NULL)
{
#if DBG
KdPrint(( "NDS32: ReadObject_SomeAttrs LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
RtlCopyMemory( (LPBYTE) ((LPBYTE) (lpTempBuff) + lpNdsBuffer->dwReplyBufferSize),
(LPBYTE) ((LPBYTE) (lpCurrBuff) + dwCopyOffset),
(dwCurrBuffSize - dwCopyOffset) );
lpNdsBuffer->lpReplyBuffer = lpTempBuff;
lpNdsBuffer->dwReplyBufferSize += (dwCurrBuffSize - dwCopyOffset);
dwNumEntries += dwCurrNumEntries;
RtlZeroMemory(lpCurrBuff, dwCurrBuffSize);
} while ( dwIterHandle != NDS_NO_MORE_ITERATIONS );
lpNdsBuffer->dwNumberOfReplyEntries = dwNumEntries;
lpNdsBuffer->dwReplyInformationType = dwInfoType;
(void) LocalFree( (HLOCAL) lpCurrBuff );
return NO_ERROR;
ErrorExit :
if ( lpCurrBuff )
{
(void) LocalFree( (HLOCAL) lpCurrBuff );
lpCurrBuff = NULL;
}
if ( lpNdsBuffer->lpReplyBuffer )
{
(void) LocalFree( (HLOCAL) lpNdsBuffer->lpReplyBuffer );
lpNdsBuffer->lpReplyBuffer = NULL;
lpNdsBuffer->dwReplyBufferSize = 0;
}
return status;
}
DWORD
Search_AllAttrs(
IN HANDLE hStartFromObject,
IN DWORD dwInformationType,
IN DWORD dwScope,
IN BOOL fDerefAliases,
IN LPQUERY_TREE lpQueryTree,
IN OUT LPDWORD lpdwIterHandle,
IN OUT HANDLE * lphOperationData )
{
DWORD status;
DWORD nwstatus;
NTSTATUS ntstatus;
LPNDS_BUFFER lpNdsBuffer = NULL;
LPNDS_BUFFER lpNdsQueryTreeBuffer = NULL;
DWORD dwReplyLength;
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hStartFromObject;
DWORD dwIterHandle;
DWORD dwNumEntries;
DWORD dwAmountOfNodesSearched;
DWORD dwLengthOfSearch;
DWORD iter;
//
// Search NCP parameters
//
DWORD dwFlags = fDerefAliases ?
NDS_DEREF_ALIASES :
NDS_DONT_DEREF_ALIASES;
DWORD dwNumNodes = 0;
DWORD dwNumAttributes = 0;
DWORD dwInfoType = dwInformationType;
LPBYTE FixedPortion;
LPWSTR EndOfVariableData;
BOOL FitInBuffer = TRUE;
if ( *lphOperationData == NULL )
{
//
// This is the first time that NwNdsSearch has been called,
// need to create a hOperationData buffer . . .
//
status = NwNdsCreateBuffer( NDS_SEARCH,
(HANDLE *) &lpNdsBuffer );
if ( status )
{
goto ErrorExit;
}
//
// Not specifying any particular attributes in the search request.
//
(void) LocalFree( (HLOCAL) lpNdsBuffer->lpRequestBuffer );
lpNdsBuffer->lpRequestBuffer = NULL;
lpNdsBuffer->dwRequestBufferSize = 0;
lpNdsBuffer->dwRequestAvailableBytes = 0;
lpNdsBuffer->dwNumberOfRequestEntries = 0;
lpNdsBuffer->dwLengthOfRequestData = 0;
//
// Reasonable guess is that the response buffer needs to be 16K bytes.
//
lpNdsBuffer->dwReplyBufferSize = SIXTEEN_KB;
}
else if ( ((LPNDS_BUFFER) *lphOperationData)->dwBufferId == NDS_SIGNATURE &&
((LPNDS_BUFFER) *lphOperationData)->dwOperation == NDS_SEARCH &&
((LPNDS_BUFFER) *lphOperationData)->lpReplyBuffer )
{
//
// This seems to be a sub-sequent call to NwNdsSearch with a resume
// handle, need to clean up the hOperationData buffer from the last
// time this was called.
//
lpNdsBuffer = (LPNDS_BUFFER) *lphOperationData;
(void) LocalFree( (HLOCAL) lpNdsBuffer->lpReplyBuffer );
lpNdsBuffer->lpReplyBuffer = NULL;
lpNdsBuffer->dwReplyAvailableBytes = 0;
lpNdsBuffer->dwNumberOfReplyEntries = 0;
lpNdsBuffer->dwLengthOfReplyData = 0;
if ( lpNdsBuffer->lpIndexBuffer )
{
(void) LocalFree( (HLOCAL) lpNdsBuffer->lpIndexBuffer );
lpNdsBuffer->lpIndexBuffer = NULL;
lpNdsBuffer->dwIndexAvailableBytes = 0;
lpNdsBuffer->dwNumberOfIndexEntries = 0;
lpNdsBuffer->dwLengthOfIndexData = 0;
}
//
// Since the last call to NwNdsSearch needed a bigger buffer for all
// of the response data, let's continue this time with a bigger reply
// buffer. We grow the buffer up to a point, 128K bytes.
//
if ( lpNdsBuffer->dwReplyBufferSize < SIXTY_FOUR_KB )
{
lpNdsBuffer->dwReplyBufferSize *= 2;
}
}
else
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
status = NwNdsCreateBuffer( NDS_SEARCH,
(HANDLE *) &lpNdsQueryTreeBuffer );
if ( status )
{
goto ErrorExit;
}
//
// Prepare request buffer stream with search query.
//
status = WriteQueryTreeToBuffer( lpQueryTree, lpNdsQueryTreeBuffer );
if ( status )
{
goto ErrorExit;
}
lpNdsBuffer->lpReplyBuffer =
(PVOID) LocalAlloc( LPTR, lpNdsBuffer->dwReplyBufferSize );
//
// Check that the memory allocation was successful.
//
if ( lpNdsBuffer->lpReplyBuffer == NULL )
{
#if DBG
KdPrint(( "NDS32: Search_AllAttrs LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
/*
//
// This is the format of a version 3 search request ...
//
ntstatus = FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_SEARCH,
lpNdsBuffer->lpReplyBuffer,
lpNdsBuffer->dwReplyBufferSize,
&dwReplyLength,
"DDDDDDDDDDr",
0x00000003, // Version
dwFlags,
*lpdwIterHandle,
lpNdsObject->ObjectId, // Id of object to
// start search from.
dwScope,
dwNumNodes,
dwInfoType,
0x0000281D, // Flags??
0x741E0000, // ??
(DWORD) TRUE, // All attributes?
lpNdsQueryTreeBuffer->lpRequestBuffer,
(WORD)lpNdsQueryTreeBuffer->dwLengthOfRequestData );
*/
ntstatus = FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_SEARCH,
lpNdsBuffer->lpReplyBuffer,
lpNdsBuffer->dwReplyBufferSize,
&dwReplyLength,
"DDDDDDDDDr",
0x00000002, // Version
dwFlags,
*lpdwIterHandle,
lpNdsObject->ObjectId, // Id of object to
// start search from.
dwScope,
dwNumNodes,
dwInfoType,
(DWORD) TRUE, // All attributes?
dwNumAttributes,
lpNdsQueryTreeBuffer->lpRequestBuffer,
(WORD)lpNdsQueryTreeBuffer->dwLengthOfRequestData );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
ntstatus = ParseResponse( lpNdsBuffer->lpReplyBuffer,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( nwstatus )
{
SetLastError( MapNetwareErrorCode( nwstatus ) );
status = nwstatus;
goto ErrorExit;
}
ntstatus = ParseResponse( (BYTE *) lpNdsBuffer->lpReplyBuffer,
dwReplyLength,
"G_DDDDD",
sizeof(DWORD),
&dwIterHandle,
&dwAmountOfNodesSearched,
&dwInfoType,
&dwLengthOfSearch,
&dwNumEntries );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
//
// Finished the search call, free up lpNDsQueryTreeBuffer
//
(void) NwNdsFreeBuffer( (HANDLE) lpNdsQueryTreeBuffer );
lpNdsQueryTreeBuffer = NULL;
lpNdsBuffer->dwNumberOfReplyEntries = dwNumEntries;
lpNdsBuffer->dwReplyInformationType = dwInfoType;
*lpdwIterHandle = dwIterHandle;
*lphOperationData = (HANDLE) lpNdsBuffer;
//
// Keep the search from object path . . .
//
wcscpy( lpNdsBuffer->szPath, lpNdsObject->szContainerName );
return NO_ERROR;
ErrorExit :
if ( lpNdsBuffer )
{
(void) NwNdsFreeBuffer( (HANDLE) lpNdsBuffer );
lpNdsBuffer = NULL;
}
if ( lpNdsQueryTreeBuffer )
{
(void) NwNdsFreeBuffer( (HANDLE) lpNdsQueryTreeBuffer );
lpNdsQueryTreeBuffer = NULL;
}
return status;
}
DWORD
Search_SomeAttrs(
IN HANDLE hStartFromObject,
IN DWORD dwInformationType,
IN DWORD dwScope,
IN BOOL fDerefAliases,
IN LPQUERY_TREE lpQueryTree,
IN OUT LPDWORD lpdwIterHandle,
IN OUT HANDLE * lphOperationData )
{
DWORD status;
DWORD nwstatus;
NTSTATUS ntstatus;
LPNDS_BUFFER lpNdsBuffer = (LPNDS_BUFFER) *lphOperationData;
LPNDS_BUFFER lpNdsQueryTreeBuffer = NULL;
DWORD dwReplyLength;
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hStartFromObject;
DWORD dwIterHandle;
DWORD dwNumEntries;
DWORD dwAmountOfNodesSearched;
DWORD dwLengthOfSearch;
DWORD iter;
//
// Search NCP parameters
//
DWORD dwFlags = fDerefAliases ?
NDS_DEREF_ALIASES :
NDS_DONT_DEREF_ALIASES;
DWORD dwNumNodes = 0;
DWORD dwInfoType = dwInformationType;
LPBYTE FixedPortion;
LPWSTR EndOfVariableData;
BOOL FitInBuffer = TRUE;
//
// A quick check of the buffer passed to us.
//
if ( lpNdsBuffer->dwBufferId != NDS_SIGNATURE ||
lpNdsBuffer->dwOperation != NDS_SEARCH )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Prepare request buffer stream with search query.
//
status = NwNdsCreateBuffer( NDS_SEARCH,
(HANDLE *) &lpNdsQueryTreeBuffer );
if ( status )
{
goto ErrorExit;
}
status = WriteQueryTreeToBuffer( lpQueryTree, lpNdsQueryTreeBuffer );
if ( status )
{
goto ErrorExit;
}
if ( lpNdsBuffer->lpReplyBuffer == NULL ||
lpNdsBuffer->dwReplyBufferSize == 0 )
{
//
// Reasonable guess is that the initial response buffer needs to
// be 16K bytes.
//
lpNdsBuffer->dwReplyBufferSize = SIXTEEN_KB;
}
if ( lpNdsBuffer->lpReplyBuffer )
{
//
// This seems to be a sub-sequent call to NwNdsSearch,
// need to clean up the hOperationData buffer from the last
// time this was called.
//
(void) LocalFree( (HLOCAL) lpNdsBuffer->lpReplyBuffer );
lpNdsBuffer->lpReplyBuffer = NULL;
lpNdsBuffer->dwReplyAvailableBytes = 0;
lpNdsBuffer->dwNumberOfReplyEntries = 0;
lpNdsBuffer->dwLengthOfReplyData = 0;
if ( lpNdsBuffer->lpIndexBuffer )
{
(void) LocalFree( (HLOCAL) lpNdsBuffer->lpIndexBuffer );
lpNdsBuffer->lpIndexBuffer = NULL;
lpNdsBuffer->dwIndexAvailableBytes = 0;
lpNdsBuffer->dwNumberOfIndexEntries = 0;
lpNdsBuffer->dwLengthOfIndexData = 0;
}
//
// Since the last call to NwNdsSearch needed a bigger buffer for all
// of the response data, let's continue this time with a bigger reply
// buffer. We grow the buffer up to a point, 64K bytes.
//
if ( lpNdsBuffer->dwReplyBufferSize < SIXTY_FOUR_KB )
{
lpNdsBuffer->dwReplyBufferSize *= 2;
}
}
lpNdsBuffer->lpReplyBuffer =
(PVOID) LocalAlloc( LPTR, lpNdsBuffer->dwReplyBufferSize );
//
// Check that the memory allocation was successful.
//
if ( lpNdsBuffer->lpReplyBuffer == NULL )
{
#if DBG
KdPrint(( "NDS32: Search_SomeAttrs LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
/*
//
// This is the format of a version 3 search request ...
//
ntstatus = FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_SEARCH,
lpNdsBuffer->lpReplyBuffer,
lpNdsBuffer->dwReplyBufferSize,
&dwReplyLength,
"DDDDDDDDDDrr",
0x00000003,
dwFlags,
*lpdwIterHandle,
lpNdsObject->ObjectId, // Id of object to
// start search from.
dwScope,
dwNumNodes,
dwInfoType,
0x0000281D, // (DWORD) FALSE,// All attributes?
0x741E0000, // dwNumAttributes,
lpNdsBuffer->dwNumberOfRequestEntries,
lpNdsBuffer->lpRequestBuffer,
lpNdsBuffer->dwLengthOfRequestData,
lpNdsQueryTreeBuffer->lpRequestBuffer,
(WORD)lpNdsQueryTreeBuffer->dwLengthOfRequestData );
*/
ntstatus = FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_SEARCH,
lpNdsBuffer->lpReplyBuffer,
lpNdsBuffer->dwReplyBufferSize,
&dwReplyLength,
"DDDDDDDDDrr",
0x00000002,
dwFlags,
*lpdwIterHandle,
lpNdsObject->ObjectId, // Id of object to
// start search from.
dwScope,
dwNumNodes,
dwInfoType,
(DWORD) FALSE, // All attributes?
lpNdsBuffer->dwNumberOfRequestEntries,
lpNdsBuffer->lpRequestBuffer,
lpNdsBuffer->dwLengthOfRequestData,
lpNdsQueryTreeBuffer->lpRequestBuffer,
(WORD)lpNdsQueryTreeBuffer->dwLengthOfRequestData );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
ntstatus = ParseResponse( lpNdsBuffer->lpReplyBuffer,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
if ( nwstatus )
{
SetLastError( MapNetwareErrorCode( nwstatus ) );
status = nwstatus;
goto ErrorExit;
}
ntstatus = ParseResponse( (BYTE *) lpNdsBuffer->lpReplyBuffer,
dwReplyLength,
"G_DDDDD",
sizeof(DWORD),
&dwIterHandle,
&dwAmountOfNodesSearched,
&dwInfoType,
&dwLengthOfSearch,
&dwNumEntries );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: ReadAttrDef_SomeAttrs: The read object response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
status = (DWORD) UNSUCCESSFUL;
goto ErrorExit;
}
//
// Finished the search call, free up lpNDsQueryTreeBuffer
//
(void) NwNdsFreeBuffer( (HANDLE) lpNdsQueryTreeBuffer );
lpNdsQueryTreeBuffer = NULL;
lpNdsBuffer->dwNumberOfReplyEntries = dwNumEntries;
lpNdsBuffer->dwReplyInformationType = dwInfoType;
*lpdwIterHandle = dwIterHandle;
*lphOperationData = (HANDLE) lpNdsBuffer;
//
// Keep the search from object path . . .
//
wcscpy( lpNdsBuffer->szPath, lpNdsObject->szContainerName );
return NO_ERROR;
ErrorExit :
if ( lpNdsQueryTreeBuffer )
{
(void) NwNdsFreeBuffer( (HANDLE) lpNdsQueryTreeBuffer );
lpNdsQueryTreeBuffer = NULL;
}
return status;
}
VOID
GetSubTreeData( IN DWORD NdsRawDataPtr,
OUT LPDWORD lpdwEntryId,
OUT LPDWORD lpdwSubordinateCount,
OUT LPDWORD lpdwModificationTime,
OUT LPDWORD lpdwClassNameLen,
OUT LPWSTR * lpszClassName,
OUT LPDWORD lpdwObjectNameLen,
OUT LPWSTR * lpszObjectName )
{
PNDS_RESPONSE_SUBORDINATE_ENTRY pSubEntry =
(PNDS_RESPONSE_SUBORDINATE_ENTRY) NdsRawDataPtr;
PBYTE pbRaw;
//
// The structure of a NDS_RESPONSE_SUBORDINATE_ENTRY consists of 4 DWORDs
// followed by two standard NDS format UNICODE strings. Below we jump pbRaw
// into the buffer, past the 4 DWORDs.
//
*lpdwEntryId = pSubEntry->EntryId;
*lpdwSubordinateCount = pSubEntry->SubordinateCount;
*lpdwModificationTime = pSubEntry->ModificationTime;
pbRaw = (BYTE *) pSubEntry;
pbRaw += sizeof(NDS_RESPONSE_SUBORDINATE_ENTRY);
//
// Now we get the length of the first string (Base Class).
//
*lpdwClassNameLen = * (DWORD *) pbRaw;
//
// Now we point pbRaw to the first WCHAR of the first string (Base Class).
//
pbRaw += sizeof(DWORD);
*lpszClassName = (LPWSTR) pbRaw;
//
// Move pbRaw into the buffer, past the first UNICODE string (WORD aligned)
//
pbRaw += ROUNDUP4( *lpdwClassNameLen );
//
// Now we get the length of the second string (Entry Name).
//
*lpdwObjectNameLen = * (DWORD *) pbRaw;
//
// Now we point pbRaw to the first WCHAR of the second string (Entry Name).
//
pbRaw += sizeof(DWORD);
*lpszObjectName = (LPWSTR) pbRaw;
}
LPBYTE
GetSearchResultData( IN LPBYTE lpResultBufferPtr,
OUT LPDWORD lpdwFlags,
OUT LPDWORD lpdwSubordinateCount,
OUT LPDWORD lpdwModificationTime,
OUT LPDWORD lpdwClassNameLen,
OUT LPWSTR * lpszClassName,
OUT LPDWORD lpdwObjectNameLen,
OUT LPWSTR * lpszObjectName,
OUT LPDWORD lpdwEntryInfo1,
OUT LPDWORD lpdwEntryInfo2 )
{
LPBYTE lpRaw = lpResultBufferPtr;
*lpdwFlags = * (LPDWORD) lpRaw;
lpRaw += sizeof(DWORD);
*lpdwSubordinateCount = * (LPDWORD) lpRaw;
lpRaw += sizeof(DWORD);
*lpdwModificationTime = * (LPDWORD) lpRaw;
lpRaw += sizeof(DWORD);
//
// Now we get the length of the first string (Base Class).
//
*lpdwClassNameLen = * (DWORD *) lpRaw;
//
// Now we point lpRaw to the first WCHAR of the first string (Base Class).
//
lpRaw += sizeof(DWORD);
*lpszClassName = (LPWSTR) lpRaw;
//
// Move lpRaw into the buffer, past the first UNICODE string
// (DWORD aligned)
//
lpRaw += ROUNDUP4( *lpdwClassNameLen );
//
// Now we get the length of the second string (Entry Name).
//
*lpdwObjectNameLen = * (DWORD *) lpRaw;
//
// Now we point lpRaw to the first WCHAR of the second string (Entry Name).
//
lpRaw += sizeof(DWORD);
*lpszObjectName = (LPWSTR) lpRaw;
//
// Move lpRaw into the buffer, past the second UNICODE string
// (DWORD aligned)
//
lpRaw += ROUNDUP4( *lpdwObjectNameLen );
//
// Now skip over the last two DWORDs, I don't know what they represent?
//
*lpdwEntryInfo1 = * (LPDWORD) lpRaw;
lpRaw += sizeof(DWORD);
*lpdwEntryInfo2 = * (LPDWORD) lpRaw;
lpRaw += sizeof(DWORD);
return lpRaw;
}
DWORD
WriteObjectToBuffer(
IN OUT LPBYTE * FixedPortion,
IN OUT LPWSTR * EndOfVariableData,
IN LPWSTR szObjectFullName,
IN LPWSTR szObjectName,
IN LPWSTR szClassName,
IN DWORD EntryId,
IN DWORD ModificationTime,
IN DWORD SubordinateCount,
IN DWORD NumberOfAttributes,
IN LPNDS_ATTR_INFO lpAttributeInfos )
{
BOOL FitInBuffer = TRUE;
LPNDS_OBJECT_INFO lpNdsObjectInfo = (LPNDS_OBJECT_INFO) *FixedPortion;
DWORD EntrySize = sizeof( NDS_OBJECT_INFO ) +
( wcslen( szObjectFullName ) +
wcslen( szObjectName ) +
wcslen( szClassName ) +
3 ) * sizeof( WCHAR );
EntrySize = ROUND_UP_COUNT( EntrySize, ALIGN_DWORD );
//
// See if buffer is large enough to fit the entry.
//
if (((DWORD_PTR) *FixedPortion + EntrySize) >
(DWORD_PTR) *EndOfVariableData) {
return WN_MORE_DATA;
}
lpNdsObjectInfo->dwEntryId = EntryId;
lpNdsObjectInfo->dwModificationTime = ModificationTime;
lpNdsObjectInfo->dwSubordinateCount = SubordinateCount;
lpNdsObjectInfo->dwNumberOfAttributes = NumberOfAttributes;
lpNdsObjectInfo->lpAttribute = lpAttributeInfos;
//
// Update fixed entry pointer to next entry.
//
(DWORD_PTR) (*FixedPortion) += sizeof(NDS_OBJECT_INFO);
FitInBuffer = NwlibCopyStringToBuffer(
szObjectFullName,
wcslen(szObjectFullName),
(LPCWSTR) *FixedPortion,
EndOfVariableData,
&lpNdsObjectInfo->szObjectFullName );
ASSERT(FitInBuffer);
FitInBuffer = NwlibCopyStringToBuffer(
szObjectName,
wcslen(szObjectName),
(LPCWSTR) *FixedPortion,
EndOfVariableData,
&lpNdsObjectInfo->szObjectName );
ASSERT(FitInBuffer);
FitInBuffer = NwlibCopyStringToBuffer(
szClassName,
wcslen(szClassName),
(LPCWSTR) *FixedPortion,
EndOfVariableData,
&lpNdsObjectInfo->szObjectClass );
ASSERT(FitInBuffer);
if (! FitInBuffer)
return WN_MORE_DATA;
return NO_ERROR;
}
DWORD
VerifyBufferSize(
IN LPBYTE lpRawBuffer,
IN DWORD dwBufferSize,
IN DWORD dwSyntaxID,
IN DWORD dwNumberOfValues,
OUT LPDWORD lpdwLength )
{
DWORD iter;
LPBYTE lpTemp = lpRawBuffer;
*lpdwLength = 0;
for ( iter = 0; iter < dwNumberOfValues; iter++ )
{
*lpdwLength += SizeOfASN1Structure( &lpTemp, dwSyntaxID );
}
if ( *lpdwLength > dwBufferSize )
{
return ERROR_NOT_ENOUGH_MEMORY;
}
return NO_ERROR;
}
DWORD
VerifyBufferSizeForStringList(
IN DWORD dwBufferSize,
IN DWORD dwNumberOfValues,
OUT LPDWORD lpdwLength )
{
*lpdwLength = sizeof(ASN1_TYPE_6) * dwNumberOfValues;
if ( *lpdwLength > dwBufferSize )
{
return ERROR_NOT_ENOUGH_MEMORY;
}
return NO_ERROR;
}
DWORD
WriteQueryTreeToBuffer(
IN LPQUERY_TREE lpQueryTree,
IN LPNDS_BUFFER lpNdsBuffer )
{
DWORD status;
switch( lpQueryTree->dwOperation )
{
case NDS_QUERY_OR :
case NDS_QUERY_AND :
if ( lpQueryTree->lpLVal == NULL || lpQueryTree->lpRVal == NULL )
{
#if DBG
KdPrint(( "NDS32: WriteQueryTreeToBuffer was not passed a pointer to an L or R value.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
status = WriteQueryNodeToBuffer( (LPQUERY_NODE) lpQueryTree,
lpNdsBuffer );
if ( status )
return status;
status = WriteQueryTreeToBuffer( (LPQUERY_TREE) lpQueryTree->lpLVal,
lpNdsBuffer );
if ( status )
return status;
status = WriteQueryTreeToBuffer( (LPQUERY_TREE) lpQueryTree->lpRVal,
lpNdsBuffer );
if ( status )
return status;
break;
case NDS_QUERY_NOT :
if ( lpQueryTree->lpLVal == NULL )
{
#if DBG
KdPrint(( "NDS32: WriteQueryTreeToBuffer was not passed a pointer to an L value.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
status = WriteQueryNodeToBuffer( (LPQUERY_NODE) lpQueryTree,
lpNdsBuffer );
if ( status )
return status;
status = WriteQueryTreeToBuffer( (LPQUERY_TREE) lpQueryTree->lpLVal,
lpNdsBuffer );
if ( status )
return status;
break;
case NDS_QUERY_EQUAL :
case NDS_QUERY_GE :
case NDS_QUERY_LE :
case NDS_QUERY_APPROX :
case NDS_QUERY_PRESENT :
status = WriteQueryNodeToBuffer( (LPQUERY_NODE) lpQueryTree,
lpNdsBuffer );
if ( status )
return status;
break;
default :
#if DBG
KdPrint(( "NDS32: WriteQueryTreeToBuffer was passed an unidentified operation - 0x%.8X.\n", lpQueryTree->dwOperation ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
return NO_ERROR;
}
DWORD
WriteQueryNodeToBuffer(
IN LPQUERY_NODE lpQueryNode,
IN LPNDS_BUFFER lpNdsBuffer )
{
DWORD LengthInBytes = 0;
DWORD stringLen;
LPBYTE lpTemp;
if ( lpNdsBuffer->dwRequestAvailableBytes < ONE_KB )
{
//
// Buffer to store query is getting small, need to increase
// request buffer size.
//
if ( AllocateOrIncreaseRequestBuffer( lpNdsBuffer ) != NO_ERROR )
{
#if DBG
KdPrint(( "NDS32: WriteQueryNodeToBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
}
lpTemp = (LPBYTE)&lpNdsBuffer->lpRequestBuffer[lpNdsBuffer->dwLengthOfRequestData];
switch( lpQueryNode->dwOperation )
{
case NDS_QUERY_OR :
case NDS_QUERY_AND :
if ( lpQueryNode->lpLVal == NULL || lpQueryNode->lpRVal == NULL )
{
#if DBG
KdPrint(( "NDS32: WriteQueryNodeToBuffer was not passed a pointer to an L or R value.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Write out operation
//
*(LPDWORD)lpTemp = lpQueryNode->dwOperation;
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = 2; // The number of items being ANDed or ORed.
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
break;
case NDS_QUERY_NOT :
if ( lpQueryNode->lpLVal == NULL )
{
#if DBG
KdPrint(( "NDS32: WriteQueryNodeToBuffer was not passed a pointer to an L value.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Write out operation
//
*(LPDWORD)lpTemp = lpQueryNode->dwOperation;
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
break;
case NDS_QUERY_EQUAL :
case NDS_QUERY_GE :
case NDS_QUERY_LE :
case NDS_QUERY_APPROX :
if ( lpQueryNode->lpLVal == NULL || lpQueryNode->lpRVal == NULL )
{
#if DBG
KdPrint(( "NDS32: WriteQueryNodeToBuffer was not passed a pointer to an L or R value.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Write out operation
//
*(LPDWORD)lpTemp = 0; // Zero represents ITEM in NDS
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = lpQueryNode->dwOperation;
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
switch( lpQueryNode->dwSyntaxId )
{
case NDS_SYNTAX_ID_1 :
case NDS_SYNTAX_ID_2 :
case NDS_SYNTAX_ID_3 :
case NDS_SYNTAX_ID_4 :
case NDS_SYNTAX_ID_5 :
case NDS_SYNTAX_ID_10 :
case NDS_SYNTAX_ID_20 :
//
// Write out the attribute name stored in LVal
//
stringLen = wcslen( (LPWSTR) lpQueryNode->lpLVal );
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
lpQueryNode->lpLVal,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT( (stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
LengthInBytes += ROUND_UP_COUNT( (stringLen+1) *
sizeof(WCHAR),
ALIGN_DWORD );
//
// Write out the attribute value stored in RVal
//
stringLen = wcslen( (LPWSTR) lpQueryNode->lpRVal );
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
lpQueryNode->lpRVal,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT( (stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
LengthInBytes += ROUND_UP_COUNT( (stringLen+1) *
sizeof(WCHAR),
ALIGN_DWORD );
break;
case NDS_SYNTAX_ID_7 :
//
// Write out the attribute name stored in LVal
//
stringLen = wcslen( (LPWSTR) lpQueryNode->lpLVal );
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
lpQueryNode->lpLVal,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT( (stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
LengthInBytes += ROUND_UP_COUNT( (stringLen+1) *
sizeof(WCHAR),
ALIGN_DWORD );
//
// Write out the attribute value stored in RVal
//
*(LPDWORD)lpTemp = 1; // Needs to have value 1,
// representing one byte
// even though it is padded
// out to four bytes.
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = 0; // This clears all bits of the DWORD
*(LPBYTE)lpTemp = (BYTE) (((LPASN1_TYPE_7)
lpQueryNode->lpRVal)->Boolean);
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
break;
case NDS_SYNTAX_ID_8 :
case NDS_SYNTAX_ID_22 :
case NDS_SYNTAX_ID_24 :
case NDS_SYNTAX_ID_27 :
//
// Write out the attribute name stored in LVal
//
stringLen = wcslen( (LPWSTR) lpQueryNode->lpLVal );
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
lpQueryNode->lpLVal,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT( (stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
LengthInBytes += ROUND_UP_COUNT( (stringLen+1) *
sizeof(WCHAR),
ALIGN_DWORD );
//
// Write out the attribute value stored in RVal
//
*(LPDWORD)lpTemp = sizeof( DWORD );
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = *( (LPDWORD) lpQueryNode->lpRVal );
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
break;
case NDS_SYNTAX_ID_9 :
//
// Write out the attribute name stored in LVal
//
stringLen = wcslen( (LPWSTR) lpQueryNode->lpLVal );
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
lpQueryNode->lpLVal,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT( (stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
LengthInBytes += ROUND_UP_COUNT( (stringLen+1) *
sizeof(WCHAR),
ALIGN_DWORD );
//
// Write out the attribute value stored in RVal
//
stringLen = ((LPASN1_TYPE_9) lpQueryNode->lpRVal)->Length;
*(LPDWORD)lpTemp = stringLen;
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
&((LPASN1_TYPE_9) lpQueryNode->lpRVal)->OctetString,
stringLen );
lpTemp += ROUND_UP_COUNT( stringLen, ALIGN_DWORD);
LengthInBytes += ROUND_UP_COUNT( stringLen, ALIGN_DWORD );
break;
default :
SetLastError( ERROR_NOT_SUPPORTED );
return (DWORD) UNSUCCESSFUL;
}
break;
case NDS_QUERY_PRESENT :
if ( lpQueryNode->lpLVal == NULL )
{
#if DBG
KdPrint(( "NDS32: WriteQueryNodeToBuffer was not passed a pointer to an L value.\n" ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
//
// Write out operation
//
*(LPDWORD)lpTemp = 0; // Zero represents ITEM in NDS
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
*(LPDWORD)lpTemp = lpQueryNode->dwOperation;
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
//
// Write out the attribute name stored in LVal
//
stringLen = wcslen( (LPWSTR) lpQueryNode->lpLVal );
*(LPDWORD)lpTemp = (stringLen + 1) * sizeof(WCHAR);
lpTemp += sizeof(DWORD);
LengthInBytes += sizeof(DWORD);
RtlCopyMemory( lpTemp,
lpQueryNode->lpLVal,
stringLen*sizeof(WCHAR) );
lpTemp += ROUND_UP_COUNT( (stringLen+1)*sizeof(WCHAR),
ALIGN_DWORD);
LengthInBytes += ROUND_UP_COUNT( (stringLen+1) *
sizeof(WCHAR),
ALIGN_DWORD );
break;
default :
#if DBG
KdPrint(( "NDS32: WriteQueryNodeToBuffer was passed an unidentified operation - 0x%.8X.\n", lpQueryNode->dwOperation ));
#endif
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
lpNdsBuffer->dwRequestAvailableBytes -= LengthInBytes;
lpNdsBuffer->dwLengthOfRequestData += LengthInBytes;
return NO_ERROR;
}
DWORD
NwNdsGetServerDN(
IN HANDLE hTree,
OUT LPWSTR szServerDN )
{
DWORD nwstatus;
DWORD status = NO_ERROR;
NTSTATUS ntstatus = STATUS_SUCCESS;
DWORD dwReplyLength;
BYTE NdsReply[NDS_BUFFER_SIZE];
LPNDS_OBJECT_PRIV lpNdsObject = (LPNDS_OBJECT_PRIV) hTree;
if ( lpNdsObject == NULL ||
lpNdsObject->Signature != NDS_SIGNATURE )
{
SetLastError( ERROR_INVALID_PARAMETER );
return (DWORD) UNSUCCESSFUL;
}
ntstatus =
FragExWithWait( lpNdsObject->NdsTree,
NETWARE_NDS_FUNCTION_GET_SERVER_ADDRESS,
NdsReply,
NDS_BUFFER_SIZE,
&dwReplyLength,
NULL );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsGetServerInfo: The call to FragExWithWait failed with 0x%.8X.\n", ntstatus ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
ntstatus = ParseResponse( NdsReply,
dwReplyLength,
"GD",
&nwstatus );
if ( !NT_SUCCESS( ntstatus ) )
{
#if DBG
KdPrint(( "NDS32: NwNdsGetServerInfo: The get server information response was undecipherable.\n" ));
#endif
SetLastError( RtlNtStatusToDosError( ntstatus ) );
return (DWORD) UNSUCCESSFUL;
}
if ( nwstatus )
{
SetLastError( MapNetwareErrorCode( nwstatus ) );
return nwstatus;
}
else
{
LPBYTE lpByte = NdsReply;
DWORD dwStrLen = 0;
DWORD dwNumPartitions = 0;
//
// Skip past status return code ...
//
lpByte += sizeof( DWORD );
//
// Skip past the length value of the Server DN string ...
//
lpByte += sizeof( DWORD );
wcscpy( szServerDN, (LPWSTR) lpByte );
return NO_ERROR;
}
}
DWORD
AllocateOrIncreaseSyntaxBuffer(
IN LPNDS_BUFFER lpNdsBuffer )
{
if ( lpNdsBuffer->lpSyntaxBuffer )
{
LPBYTE lpTempBuffer = NULL;
//
// Need to reallocate buffer to a bigger size.
//
lpTempBuffer = (LPBYTE) LocalReAlloc(
(HLOCAL) lpNdsBuffer->lpSyntaxBuffer,
lpNdsBuffer->dwSyntaxBufferSize + FOUR_KB,
LPTR );
if ( lpTempBuffer )
{
lpNdsBuffer->lpSyntaxBuffer = lpTempBuffer;
}
else
{
lpTempBuffer = (LPBYTE) LocalAlloc( LPTR,
lpNdsBuffer->dwSyntaxBufferSize +
FOUR_KB );
if ( lpTempBuffer )
{
RtlCopyMemory( lpTempBuffer,
lpNdsBuffer->lpSyntaxBuffer,
lpNdsBuffer->dwSyntaxBufferSize );
LocalFree( lpNdsBuffer->lpSyntaxBuffer );
lpNdsBuffer->lpSyntaxBuffer = lpTempBuffer;
}
else
{
LocalFree( lpNdsBuffer->lpSyntaxBuffer );
lpNdsBuffer->lpSyntaxBuffer = NULL;
}
}
}
else
{
//
// Need to allocate a 4K byte buffer.
//
lpNdsBuffer->lpSyntaxBuffer = (LPBYTE) LocalAlloc( LPTR,
FOUR_KB );
lpNdsBuffer->dwSyntaxBufferSize = 0;
lpNdsBuffer->dwSyntaxAvailableBytes = 0;
}
if ( lpNdsBuffer->lpSyntaxBuffer == NULL )
{
#if DBG
KdPrint(( "NDS32: AllocateOrIncreaseSyntaxBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
lpNdsBuffer->dwSyntaxBufferSize += FOUR_KB;
lpNdsBuffer->dwSyntaxAvailableBytes += FOUR_KB;
return NO_ERROR;
}
DWORD
AllocateOrIncreaseRequestBuffer(
IN LPNDS_BUFFER lpNdsBuffer )
{
if ( lpNdsBuffer->lpRequestBuffer )
{
LPBYTE lpTempBuffer = NULL;
//
// Need to reallocate buffer to a bigger size.
//
lpTempBuffer = (LPBYTE) LocalReAlloc(
(HLOCAL) lpNdsBuffer->lpRequestBuffer,
lpNdsBuffer->dwRequestBufferSize + TWO_KB,
LPTR );
if ( lpTempBuffer )
{
lpNdsBuffer->lpRequestBuffer = lpTempBuffer;
}
else
{
lpTempBuffer = (LPBYTE) LocalAlloc( LPTR,
lpNdsBuffer->dwRequestBufferSize +
TWO_KB );
if ( lpTempBuffer )
{
RtlCopyMemory( lpTempBuffer,
lpNdsBuffer->lpRequestBuffer,
lpNdsBuffer->dwRequestBufferSize );
LocalFree( lpNdsBuffer->lpRequestBuffer );
lpNdsBuffer->lpRequestBuffer = lpTempBuffer;
}
else
{
LocalFree( lpNdsBuffer->lpRequestBuffer );
lpNdsBuffer->lpRequestBuffer = NULL;
}
}
}
else
{
//
// Need to allocate a 2K byte buffer.
//
lpNdsBuffer->lpRequestBuffer = (LPBYTE) LocalAlloc( LPTR,
TWO_KB );
lpNdsBuffer->dwRequestBufferSize = 0;
lpNdsBuffer->dwRequestAvailableBytes = 0;
}
if ( lpNdsBuffer->lpRequestBuffer == NULL )
{
#if DBG
KdPrint(( "NDS32: AllocateOrIncreaseRequestBuffer LocalAlloc Failed 0x%.8X\n", GetLastError() ));
#endif
SetLastError( ERROR_NOT_ENOUGH_MEMORY );
return (DWORD) UNSUCCESSFUL;
}
lpNdsBuffer->dwRequestBufferSize += TWO_KB;
lpNdsBuffer->dwRequestAvailableBytes += TWO_KB;
return NO_ERROR;
}
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