windows-nt/Source/XPSP1/NT/com/rpc/ndr20/srvout.cxx

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/************************************************************************
Copyright (c) 1993 - 1999 Microsoft Corporation
Module Name :
srvout.c
Abstract :
Contains routines for support of [out] parameters on server side during
unmarshalling phase. This includes deferral, allocation and handle
initialization.
Author :
Bruce McQuistan (brucemc) 12/93.
Revision History :
DKays 10/94 Major comment and code clean up.
***********************************************************************/
#include "ndrp.h"
#include "hndl.h"
#include "interp.h"
void
NdrOutInit(
PMIDL_STUB_MESSAGE pStubMsg,
PFORMAT_STRING pFormat,
uchar ** ppArg
)
/*++
Routine Description :
This routine is called to manage server side issues for [out] params
such as allocation and context handle initialization. Due to the fact
that for [out] conformant objects on stack, their size descriptors may
not have been unmarshalled when we need to know their size, this routine
must be called after all other unmarshalling has occurred. Really, we
could defer only [out], conformant data, but the logic in walking the
format string to determine if an object is conformant does not warrant
that principle, so all [out] data is deferred.
Arguments :
pStubMsg - Pointer to stub message.
pFormat - Format string description for the type.
ppArg - Location of argument on stack.
Return :
None.
--*/
{
// This must be a signed long!
LONG_PTR Size;
//
// Check for a non-Interface pointer (they have a much different format
// than regular pointers).
//
if ( IS_BASIC_POINTER(*pFormat) )
{
//
// Check for a pointer to a basetype (we don't have to worry about
// a non-sized string pointer because these are not allowed as [out]
// only.
//
if ( SIMPLE_POINTER(pFormat[1]) )
{
Size = SIMPLE_TYPE_MEMSIZE(pFormat[2]);
goto DoAlloc;
}
//
// Check for a pointer to a pointer.
//
if ( POINTER_DEREF(pFormat[1]) )
{
Size = PTR_MEM_SIZE;
goto DoAlloc;
}
// We have a pointer to complex type.
pFormat += 2;
pFormat += *(signed short *)pFormat;
}
if ( *pFormat == FC_BIND_CONTEXT )
{
NDR_SCONTEXT Context;
Context = NdrContextHandleInitialize( pStubMsg,
pFormat );
if ( ! Context )
RpcRaiseException( RPC_X_SS_CONTEXT_MISMATCH );
NdrSaveContextHandle(
pStubMsg,
Context,
ppArg,
pFormat );
return;
}
//
// Don't initialize tag params if they have a tag routine since they
// aren't on the stack in this case.
//
if ( FC_CS_TAG == *pFormat )
{
NDR_CS_TAG_FORMAT *pTagFormat = (NDR_CS_TAG_FORMAT *) pFormat;
if ( NDR_INVALID_TAG_ROUTINE_INDEX != pTagFormat->TagRoutineIndex )
return;
}
//
// If we get here we have to make a call to size a complex type.
//
Size = (LONG_PTR) NdrpMemoryIncrement( pStubMsg,
0,
pFormat );
DoAlloc:
//
// Check for a negative size. This an application error condition for
// signed size specifiers.
//
if ( Size < 0 )
RpcRaiseException( RPC_X_INVALID_BOUND );
*ppArg = (uchar*)NdrAllocate( pStubMsg, (size_t) Size);
MIDL_memset( *ppArg, 0, (size_t) Size );
// We are almost done, except for an out ref to ref to ... etc.
// If this is the case keep allocating pointees of ref pointers.
if ( *pFormat == FC_RP && POINTER_DEREF(pFormat[1]) )
{
pFormat += 2;
pFormat += *(signed short *)pFormat;
if ( *pFormat == FC_RP )
NdrOutInit( pStubMsg, pFormat, (uchar **) *ppArg );
}
}
void
NdrPartialIgnoreServerInitialize(
PMIDL_STUB_MESSAGE pStubMsg,
void ** ppMemory,
PFORMAT_STRING pFormat
)
{
if ( *ppMemory)
{
NdrOutInit( pStubMsg,
pFormat,
(uchar**)ppMemory );
}
}