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ce47f986d8
NT4/private/rpc/ndr20/mrshlp.c
Microsoft ce47f986d8 First commit
2020-09-30 17:12:29 +02:00

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/*+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
Copyright (c) 1993 Microsoft Corporation
Module Name :
mrshlp.c
Abstract :
This file contains the routines for marshalling an array's or a structure's
embedded pointers and for computing conformance and variance counts and
union switch values.
Author :
David Kays dkays September 1993.
Revision History :
---------------------------------------------------------------------*/
#include "ndrp.h"
PFORMAT_STRING
NdrpEmbeddedPointerMarshall(
PMIDL_STUB_MESSAGE pStubMsg,
uchar * pMemory,
PFORMAT_STRING pFormat )
/*++
Routine Description :
Marshalls an array's or a structure's embedded pointers.
Arguments :
pStubMsg - Pointer to the stub message.
pMemory - Pointer to the structure or array whose embedded pointers
are being marshalled.
pFormat - The format string pointer layout. Should point to the
pointer layout's beginning FC_PP character upon entry.
Return :
Format string pointer after the pointer layout.
--*/
{
uchar ** ppMemPtr;
uchar * pBufPtr;
uchar * pBufferMark;
uchar * pMemorySave;
uchar * pBufferSave;
long MaxCountSave, OffsetSave;
MaxCountSave = pStubMsg->MaxCount;
OffsetSave = pStubMsg->Offset;
//
// Check if we're handling pointers in a complex struct or array,
// and re-set the stub message buffer pointer if so.
//
if ( pStubMsg->PointerBufferMark )
{
pBufferSave = pStubMsg->Buffer;
pStubMsg->Buffer = pStubMsg->PointerBufferMark;
pStubMsg->PointerBufferMark = 0;
}
else
pBufferSave = 0;
pMemorySave = pStubMsg->Memory;
// This is where the embedding structure or array begins in the buffer.
pBufferMark = pStubMsg->BufferMark;
//
// The Memory field in the stub message keeps track of the pointer to
// the current embedding structure or array. This is needed to handle
// size/length pointers, so that we can get a pointer to the current
// embedding struct when computing conformance and variance.
//
pStubMsg->Memory = pMemory;
// Skip FC_PP and FC_PAD.
pFormat += 2;
for (;;)
{
if ( *pFormat == FC_END )
{
pStubMsg->Memory = pMemorySave;
if ( pBufferSave )
{
pStubMsg->PointerBufferMark = pStubMsg->Buffer;
pStubMsg->Buffer = pBufferSave;
}
return pFormat;
}
//
// Check for FC_FIXED_REPEAT and FC_VARIABLE_REPEAT.
//
if ( *pFormat != FC_NO_REPEAT )
{
pStubMsg->MaxCount = MaxCountSave;
pStubMsg->Offset = OffsetSave;
pStubMsg->BufferMark = pBufferMark;
pFormat = NdrpEmbeddedRepeatPointerMarshall( pStubMsg,
pMemory,
pFormat );
// Continue to the next pointer.
continue;
}
// Compute the pointer to the pointer to marshall.
ppMemPtr = (uchar **)(pMemory + *((signed short *)(pFormat + 2)));
//
// Compute the location in the buffer where the pointer's value will be
// marshalled. Needed for full pointers.
//
pBufPtr = pBufferMark + *((signed short *)(pFormat + 4));
// Increment to the pointer description.
pFormat += 6;
//
// Now marshall the pointer.
//
NdrpPointerMarshall( pStubMsg,
pBufPtr,
*ppMemPtr,
pFormat );
// Increment to the next pointer description.
pFormat += 4;
} // for
}
PFORMAT_STRING
NdrpEmbeddedRepeatPointerMarshall(
PMIDL_STUB_MESSAGE pStubMsg,
uchar * pMemory,
PFORMAT_STRING pFormat )
/*++
Routine Description :
Marshalls an array's embedded pointers.
Arguments :
pStubMsg - Pointer to the stub message.
pMemory - Array whose embedded pointers are being marshalled.
pFormat - Pointer layout format string description.
Return :
Format string pointer after the pointer layout.
--*/
{
uchar ** ppMemPtr;
uchar * pBufPtr;
PFORMAT_STRING pFormatSave;
uchar * pMemorySave;
uchar * pBufferMark;
ulong RepeatCount, RepeatIncrement, Pointers, PointersSave;
pMemorySave = pStubMsg->Memory;
//
// This is where the current embedding structure or array begins in
// the buffer.
//
pBufferMark = pStubMsg->BufferMark;
// Get the number of shipped elements in the array.
switch ( *pFormat )
{
case FC_FIXED_REPEAT :
pFormat += 2;
RepeatCount = *((ushort *)pFormat);
break;
case FC_VARIABLE_REPEAT :
RepeatCount = pStubMsg->MaxCount;
//
// Check if this variable repeat instance also has a variable
// offset (this would be the case for a conformant varying array
// of pointers). If so then increment the memory pointer by the
// increment size time the variance offset.
//
if ( pFormat[1] == FC_VARIABLE_OFFSET )
pMemory += *((ushort *)(pFormat + 2)) * pStubMsg->Offset;
// else pFormat[1] == FC_FIXED_OFFSET - do nothing
break;
default :
NDR_ASSERT(0,"NdrpEmbeddedRepeatPointerMarshall : bad format char");
RpcRaiseException( RPC_S_INTERNAL_ERROR );
return 0;
}
// Increment format string to increment field.
pFormat += 2;
// Get the increment amount between successive pointers.
RepeatIncrement = *((ushort *)pFormat)++;
//
// Add the offset to the beginning of this array to the Memory
// pointer. This is the offset from the current embedding structure
// or array to the array whose pointers we're marshalling.
//
pStubMsg->Memory += *((ushort *)pFormat)++;
// Get the number of pointers in this repeat instance.
PointersSave = Pointers = *((ushort *)pFormat)++;
pFormatSave = pFormat;
//
// Loop over the number of shipped elements of the array.
//
for ( ; RepeatCount--;
pBufferMark += RepeatIncrement,
pMemory += RepeatIncrement,
pStubMsg->Memory += RepeatIncrement )
{
pFormat = pFormatSave;
Pointers = PointersSave;
//
// Loop over the number of pointer per array element (could be
// greater than one for an array of structures).
//
for ( ; Pointers--; )
{
ppMemPtr = (uchar **)(pMemory + *((signed short *)pFormat)++);
pBufPtr = pBufferMark + *((signed short *)pFormat)++;
NdrpPointerMarshall( pStubMsg,
pBufPtr,
*ppMemPtr,
pFormat );
pFormat += 4;
}
}
pStubMsg->Memory = pMemorySave;
// Return the format string pointer past the pointer descriptions.
return pFormatSave + PointersSave * 8;
}
ulong
NdrpComputeConformance (
PMIDL_STUB_MESSAGE pStubMsg,
uchar * pMemory,
PFORMAT_STRING pFormat )
/*++
Routine Description :
This routine computes the conformant size for an array or the switch_is
value for a union.
Arguments :
pStubMsg - Pointer to the stub message.
pMemory - Pointer to the array, string, or union whose size or switch_is
is being computed. This is ignored for top level parameters.
pFormat - Format string description of the array, string, or union.
Return :
The array or string size or the union switch_is.
--*/
{
void * pCount;
long Count;
static uchar Increments[] =
{
4, // Conformant array.
4, // Conformant varying array.
0, 0, // Fixed arrays - unused.
0, 0, // Varying arrays - unused.
4, // Complex array.
2, // Conformant char string.
2, // Conformant byte string.
4, // Conformant stringable struct.
2, // Conformant wide char string.
0, 0, 0, 0, // Non-conformant strings - unused.
0, // Encapsulated union - unused.
2, // Non-encapsulated union.
2, // Byte count pointer.
0, 0, // Xmit/Rep as - unused.
2 // Interface pointer.
};
//
// Advance the format string to the size_is, switch_is, iid_is, or
// byte count description.
//
pFormat += Increments[*pFormat - FC_CARRAY];
pCount = 0;
//
// First check if this is a callback.
//
if ( pFormat[1] == FC_CALLBACK )
{
uchar * pOldStackTop;
ushort Index;
// Index into expression callback routines table.
Index = *((ushort *)(pFormat + 2));
NDR_ASSERT(pStubMsg->StubDesc->apfnExprEval != 0,
"NdrpComputeConformance : no expr eval routines");
NDR_ASSERT(pStubMsg->StubDesc->apfnExprEval[Index] != 0,
"NdrpComputeConformance : bad expr eval routine index");
pOldStackTop = pStubMsg->StackTop;
//
// The callback routine uses the StackTop field of the stub message
// to base it's offsets from. So if this is a complex attribute for
// an embedded field of a structure then set StackTop equal to the
// pointer to the structure.
//
if ( (*pFormat & 0xf0) != FC_TOP_LEVEL_CONFORMANCE )
{
if ( (*pFormat & 0xf0) == FC_POINTER_CONFORMANCE )
pMemory = pStubMsg->Memory;
pStubMsg->StackTop = pMemory;
}
//
// This call puts the result in pStubMsg->MaxCount.
//
(*pStubMsg->StubDesc->apfnExprEval[Index])( pStubMsg );
pStubMsg->StackTop = pOldStackTop;
return pStubMsg->MaxCount;
}
if ( (*pFormat & 0xf0) == FC_NORMAL_CONFORMANCE )
{
// Get the address where the conformance variable is in the struct.
pCount = pMemory + *((signed short *)(pFormat + 2));
goto ComputeConformantGetCount;
}
//
// Get a pointer to the conformance describing variable.
//
if ( (*pFormat & 0xf0) == FC_TOP_LEVEL_CONFORMANCE )
{
//
// Top level conformance. For /Os stubs, the stubs put the max
// count in the stub message. For /Oi stubs, we get the max count
// via an offset from the stack top.
//
if ( pStubMsg->StackTop )
{
pCount = pStubMsg->StackTop + *((signed short *)(pFormat + 2));
goto ComputeConformantGetCount;
}
else
{
//
// If this is top level conformance with /Os then we don't have
// to do anything, the proper conformance count is placed in the
// stub message inline in the stubs.
//
return pStubMsg->MaxCount;
}
}
//
// If we're computing the size of an embedded sized pointer then we
// use the memory pointer in the stub message, which points to the
// beginning of the embedding structure.
//
if ( (*pFormat & 0xf0) == FC_POINTER_CONFORMANCE )
{
pMemory = pStubMsg->Memory;
pCount = pMemory + *((signed short *)(pFormat + 2));
goto ComputeConformantGetCount;
}
//
// Check for constant size/switch.
//
if ( (*pFormat & 0xf0) == FC_CONSTANT_CONFORMANCE )
{
//
// The size/switch is contained in the lower three bytes of the
// long currently pointed to by pFormat.
//
Count = (long)pFormat[1] << 16;
Count |= (long) *((ushort *)(pFormat + 2));
goto ComputeConformanceEnd;
}
//
// Check for conformance of a multidimensional array element in
// a -Os stub.
//
if ( (*pFormat & 0xf0) == FC_TOP_LEVEL_MULTID_CONFORMANCE )
{
long Dimension;
//
// If pArrayInfo is non-null than we have a multi-D array. If it
// is null then we have multi-leveled sized pointers.
//
if ( pStubMsg->pArrayInfo )
{
Dimension = pStubMsg->pArrayInfo->Dimension;
pStubMsg->MaxCount = pStubMsg->pArrayInfo->MaxCountArray[Dimension];
}
else
{
Dimension = *((ushort *)(pFormat + 2));
pStubMsg->MaxCount = pStubMsg->SizePtrCountArray[Dimension];
}
return pStubMsg->MaxCount;
}
ComputeConformantGetCount:
//
// Must check now if there is a dereference op.
//
if ( pFormat[1] == FC_DEREFERENCE )
{
pCount = *(void **)pCount;
}
//
// Now get the conformance count.
//
switch ( *pFormat & 0x0f )
{
case FC_ULONG :
case FC_LONG :
Count = *((long *)pCount);
break;
case FC_ENUM16:
#if defined(__RPC_MAC__)
// Take it from the other half of the long.
Count = (long) *( ((short *)pCount) + 1);
break;
#endif
// For non Mac platforms just fall thru to ushort
case FC_USHORT :
Count = (long) *((ushort *)pCount);
break;
case FC_SHORT :
Count = (long) *((short *)pCount);
break;
case FC_USMALL :
Count = (long) *((uchar *)pCount);
break;
case FC_SMALL :
Count = (long) *((char *)pCount);
break;
default :
NDR_ASSERT(0,"NdrpComputeConformance : bad count type");
RpcRaiseException( RPC_S_INTERNAL_ERROR );
return 0;
}
//
// Check the operator.
//
switch ( pFormat[1] )
{
case FC_DIV_2 :
Count /= 2;
break;
case FC_MULT_2 :
Count *= 2;
break;
case FC_SUB_1 :
Count -= 1;
break;
case FC_ADD_1 :
Count += 1;
break;
default :
// OK
break;
}
ComputeConformanceEnd:
if ( pStubMsg )
pStubMsg->MaxCount = (ulong) Count;
return (ulong) Count;
}
void
NdrpComputeVariance (
PMIDL_STUB_MESSAGE pStubMsg,
uchar * pMemory,
PFORMAT_STRING pFormat )
/*++
Routine Description :
Computes the variance (offset and actual count) for an array.
Arguments :
pStubMsg - Pointer to the stub message.
pMemory - Pointer to the array whose variance is being computed. This
is unused for a top level parameter.
pFormat - Format string description of the array.
Return :
None.
--*/
{
void * pLength;
long Length;
//
// Advance the format string to the variance description.
//
static uchar Increments[] = { 8, // Conformant varying array.
0, 0, // Fixed arrays - unsed.
8, 12, // Varying array.
8 // Complex array.
};
pFormat += Increments[*pFormat - FC_CVARRAY];
pLength = 0;
//
// First check if this is a callback.
//
if ( pFormat[1] == FC_CALLBACK )
{
long OldMaxCount;
uchar * pOldStackTop;
ushort Index;
Index = *((ushort *)(pFormat + 2));
NDR_ASSERT(pStubMsg->StubDesc->apfnExprEval != 0,
"NdrpComputeConformance : no expr eval routines");
NDR_ASSERT(pStubMsg->StubDesc->apfnExprEval[Index] != 0,
"NdrpComputeConformance : bad expr eval routine index");
pOldStackTop = pStubMsg->StackTop;
// This gets trampled by the callback routine.
OldMaxCount = pStubMsg->MaxCount;
//
// The callback routine uses the StackTop field of the stub message
// to base it's offsets from. So if this is a complex attribute for
// an embedded field of a structure then set StackTop equal to the
// pointer to the structure.
//
if ( (*pFormat & 0xf0) != FC_TOP_LEVEL_CONFORMANCE )
{
if ( (*pFormat & 0xf0) == FC_POINTER_VARIANCE )
pMemory = pStubMsg->Memory;
pStubMsg->StackTop = pMemory;
}
//
// This puts the computed offset in pStubMsg->Offset and the length
// in pStubMsg->MaxCount.
//
(*pStubMsg->StubDesc->apfnExprEval[Index])( pStubMsg );
// Put the length in the proper field.
pStubMsg->ActualCount = pStubMsg->MaxCount;
pStubMsg->MaxCount = OldMaxCount;
pStubMsg->StackTop = pOldStackTop;
return;
}
if ( (*pFormat & 0xf0) == FC_NORMAL_VARIANCE )
{
// Get the address where the variance variable is in the struct.
pLength = pMemory + *((signed short *)(pFormat + 2));
goto ComputeVarianceGetCount;
}
//
// Get a pointer to the variance variable.
//
if ( (*pFormat & 0xf0) == FC_TOP_LEVEL_VARIANCE )
{
//
// Top level variance. For /Os stubs, the stubs put the actual
// count and offset in the stub message. For /Oi stubs, we get the
// actual count via an offset from the stack top. The first_is must
// be zero if we get here.
//
if ( pStubMsg->StackTop )
{
pLength = pStubMsg->StackTop + *((signed short *)(pFormat + 2));
goto ComputeVarianceGetCount;
}
else
{
//
// If this is top level variance with /Os then we don't have
// to do anything, the proper variance values are placed in the
// stub message inline in the stubs.
//
return;
}
}
//
// If we're computing the length of an embedded size/length pointer then we
// use the memory pointer in the stub message, which points to the
// beginning of the embedding structure.
//
if ( (*pFormat & 0xf0) == FC_POINTER_VARIANCE )
{
pMemory = pStubMsg->Memory;
pLength = pMemory + *((signed short *)(pFormat + 2));
goto ComputeVarianceGetCount;
}
//
// Check for constant length.
//
if ( (*pFormat & 0xf0) == FC_CONSTANT_VARIANCE )
{
//
// The length is contained in the lower three bytes of the
// long currently pointed to by pFormat.
//
Length = (long)pFormat[1] << 16;
Length |= (long) *((ushort *)(pFormat + 2));
goto ComputeVarianceEnd;
}
//
// Check for variance of a multidimensional array element in
// a -Os stub.
//
if ( (*pFormat & 0xf0) == FC_TOP_LEVEL_MULTID_CONFORMANCE )
{
long Dimension;
//
// If pArrayInfo is non-null than we have a multi-D array. If it
// is null then we have multi-leveled sized pointers.
//
if ( pStubMsg->pArrayInfo )
{
Dimension = pStubMsg->pArrayInfo->Dimension;
pStubMsg->Offset =
pStubMsg->pArrayInfo->OffsetArray[Dimension];
pStubMsg->ActualCount =
pStubMsg->pArrayInfo->ActualCountArray[Dimension];
}
else
{
Dimension = *((ushort *)(pFormat + 2));
pStubMsg->Offset = pStubMsg->SizePtrOffsetArray[Dimension];
pStubMsg->ActualCount = pStubMsg->SizePtrLengthArray[Dimension];
}
return;
}
ComputeVarianceGetCount:
//
// Must check now if there is a dereference op.
//
if ( pFormat[1] == FC_DEREFERENCE )
{
pLength = *(void **)pLength;
}
//
// Now get the conformance count.
//
switch ( *pFormat & 0x0f )
{
case FC_ULONG :
case FC_LONG :
Length = *((long *)pLength);
break;
case FC_USHORT :
Length = (long) *((ushort *)pLength);
break;
case FC_SHORT :
Length = (long) *((short *)pLength);
break;
case FC_USMALL :
Length = (long) *((uchar *)pLength);
break;
case FC_SMALL :
Length = (long) *((char *)pLength);
break;
default :
NDR_ASSERT(0,"NdrpComputeVariance : bad format");
RpcRaiseException( RPC_S_INTERNAL_ERROR );
return;
}
//
// Check the operator.
//
switch ( pFormat[1] )
{
case FC_DIV_2 :
Length /= 2;
break;
case FC_MULT_2 :
Length *= 2;
break;
case FC_SUB_1 :
Length -= 1;
break;
case FC_ADD_1 :
Length += 1;
break;
default :
// OK
break;
}
ComputeVarianceEnd:
// Get here if the length was computed directly.
pStubMsg->Offset = 0;
pStubMsg->ActualCount = (ulong) Length;
}
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