windows-nt/Source/XPSP1/NT/com/rpc/midl/codegen/frmtreg.cxx

/*+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
 Copyright (c) 1989-2000 Microsoft Corporation

 Module Name:
    
    frmtreg.cxx

 Abstract:

    Registry for format string reuse.

 Notes:

     This file defines reuse registry for format string fragments which may
     be reused later. 

 History:

     Mar-14-1993        GregJen        Created.

 ----------------------------------------------------------------------------*/

/****************************************************************************
 *    include files
 ***************************************************************************/

#include "becls.hxx"
#pragma hdrstop

/***********************************************************************
 * global data
 **********************************************************************/


FRMTREG_DICT::FRMTREG_DICT( FORMAT_STRING * pOurs)
        : Dictionary()
    {
    pOurFormatString = pOurs;
    }

SSIZE_T
FRMTREG_DICT::Compare( pUserType pL, pUserType pR )
    {

     FRMTREG_ENTRY *  pLeft  = (FRMTREG_ENTRY *) pL;
     FRMTREG_ENTRY *  pRight = (FRMTREG_ENTRY *) pR;

    // first, sort by string length

    int  Result = ( pLeft->EndOffset - pLeft->StartOffset ) -
                   ( pRight->EndOffset - pRight->StartOffset );

    if ( Result )
        return Result;

    long   LeftOffset   = pLeft->StartOffset;
    long   RightOffset  = pRight->StartOffset;

    unsigned char * pBuffer     = pOurFormatString->pBuffer;
    unsigned char * pBufferType = pOurFormatString->pBufferType;

    // the same format string is, of course identical
    if ( LeftOffset == RightOffset )
        return 0;

    // There is a tricky situation when the strings are apart by more than 32k.
    // In the proc format string there is no problem with that, we can optize.
    // With type format string, we optimize as this is our best bet for the
    // final accessability of fragments.

    // Sort by values of format characters

    while ( ( Result == 0 ) && ( LeftOffset < pLeft->EndOffset) )
        {

        if ( pBufferType[ LeftOffset ] != pBufferType[ RightOffset ] )
            {
            // Types don't match, force the result to be unequal.
            Result = pBufferType[ LeftOffset ] - pBufferType[ RightOffset ];
            continue;
            }

        switch ( pBufferType[ LeftOffset ] )
            {
            case FS_SHORT_TYPE_OFFSET:
                // This is a comparison for the absolute type offset.
                {
                    TypeOffsetDictElem  *pLeftTO, *pRightTO;
        
                    pLeftTO  = pOurFormatString->TypeOffsetDict.
                                                   LookupOffset( LeftOffset );
                    pRightTO = pOurFormatString->TypeOffsetDict.
                                                   LookupOffset( RightOffset );

                    Result = pLeftTO->TypeOffset - pRightTO->TypeOffset;

                    LeftOffset++; RightOffset++;
                }
                break;

            case FS_SHORT_OFFSET:
                // This is a comparison for the relative type offset.
                //
                {
                    TypeOffsetDictElem  *pLeftTO, *pRightTO;
        
                    pLeftTO  = pOurFormatString->TypeOffsetDict.
                                                   LookupOffset( LeftOffset );
                    pRightTO = pOurFormatString->TypeOffsetDict.
                                                   LookupOffset( RightOffset );

                    if ( ( pLeftTO->TypeOffset == 0 ) && 
                         ( pRightTO->TypeOffset == 0 ) )
                        Result = 0;
                    else
                        // compare absolute offsets
                        Result = ( LeftOffset + pLeftTO->TypeOffset ) -
                                 ( RightOffset + pRightTO->TypeOffset );
        
                    LeftOffset++; RightOffset++;
                }
                break;

            case FS_SHORT_STACK_OFFSET:
                // Compare stack offset - multiplatform issue.
                {
                    Result = *((short UNALIGNED *)(pBuffer + LeftOffset)) -
                             *((short UNALIGNED *)(pBuffer + RightOffset));
        
                    if ( Result == 0 )
                        {
                        BOOL f32bitServer = pCommand->Is32BitEnv();
        
                        if ( f32bitServer )
                            {
                            OffsetDictElem  *pLeftStackOffsets, *pRightStackOffsets;
        
                            pLeftStackOffsets  = pOurFormatString->OffsetDict.
                                                   LookupOffset( LeftOffset );
                            pRightStackOffsets = pOurFormatString->OffsetDict.
                                                   LookupOffset( RightOffset );
        
                            long Ilo = pLeftStackOffsets->X86Offset;
                            long Iro = pRightStackOffsets->X86Offset;
                            Result = Ilo - Iro;
                            }
                        }
        
                    LeftOffset++; RightOffset++;
                }
                break;

            case FS_PAD_MACRO:
            case FS_SIZE_MACRO:
            case FS_UNKNOWN_STACK_SIZE:
                // Can't compare those, so force the result to be unequal.
                //
                Result = LeftOffset - RightOffset;
                break;

            case FS_LONG:
                // Compare longs
                //
                Result = *((long UNALIGNED *)(pBuffer + LeftOffset)) -
                         *((long UNALIGNED *)(pBuffer + RightOffset));
        
                LeftOffset += 3; RightOffset += 3;
                break;

            case FS_SHORT:
            case FS_PARAM_FLAG_SHORT:
            case FS_MAGIC_UNION_SHORT:
            case FS_CORR_FLAG_SHORT:
                // Compare plain shorts.
                //
                Result = *((short UNALIGNED *)(pBuffer + LeftOffset)) -
                         *((short UNALIGNED *)(pBuffer + RightOffset));
        
                LeftOffset++; RightOffset++;
                break;

            case FS_FORMAT_CHARACTER:
            case FS_POINTER_FORMAT_CHARACTER:
            case FS_SMALL:
            case FS_SMALL_STACK_SIZE:
            case FS_OLD_PROC_FLAG_BYTE:
            case FS_Oi2_PROC_FLAG_BYTE:
            case FS_EXT_PROC_FLAG_BYTE:
            case FS_CORR_TYPE_BYTE:
            case FS_CONTEXT_HANDLE_FLAG_BYTE:
            default:
                // Compare bytes, format chars, bytes decorated for comments,
                //
                Result = pBuffer[ LeftOffset ] - pBuffer[ RightOffset ];
                break;
            }

        LeftOffset++; RightOffset++;
        }

    return Result;
    }


FRMTREG_ENTRY *
FRMTREG_DICT::IsRegistered(
    FRMTREG_ENTRY    *    pInfo )
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

 Routine Description:

     Search for a type with the reuse registry.

 Arguments:

     pInfo    - A pointer to the type being registered.
    
 Return Value:

     The node that gets registered.
    
 Notes:

----------------------------------------------------------------------------*/
{
    Dict_Status    Status    = Dict_Find( pInfo );

    switch( Status )
        {
        case EMPTY_DICTIONARY:
        case ITEM_NOT_FOUND:
            return (FRMTREG_ENTRY *)0;
        default:
            return (FRMTREG_ENTRY *)Dict_Curr_Item();
        }
}

FRMTREG_ENTRY *
FRMTREG_DICT::Register(
    FRMTREG_ENTRY    *    pInfo )
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

 Routine Description:

    Register a type with the dictionary.

 Arguments:
    
     pType    - A pointer to the type node.

 Return Value:

     The final inserted type.
    
 Notes:

----------------------------------------------------------------------------*/
{
        Dict_Insert( (pUserType) pInfo );
        return pInfo;
}

BOOL                
FRMTREG_DICT::GetReUseEntry( 
    FRMTREG_ENTRY * & pOut, 
    FRMTREG_ENTRY * pIn )
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

 Routine Description:

    Register a type with the dictionary.

 Arguments:
    
     pRI      - A pointer to the returned FRMTREG_ENTRY block
     pNode    - A pointer to the type node.

 Return Value:

     True if the entry was already in the table,
     False if the entry is new.
    
 Notes:

----------------------------------------------------------------------------*/
{
    FRMTREG_ENTRY    *    pRealEntry;

    if ( ( pRealEntry = IsRegistered( pIn ) ) == 0 )
        {
        pRealEntry = new FRMTREG_ENTRY( pIn->StartOffset, pIn->EndOffset );
        Register( pRealEntry );
        pOut = pRealEntry;
        return FALSE;
        }

    pOut = pRealEntry;
    pOut->UseCount++;
    return TRUE;
}
Add source files 2020-09-26 03:20:57 -05:00			`/*+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++`
			`Copyright (c) 1989-2000 Microsoft Corporation`

			`Module Name:`

			`frmtreg.cxx`

			`Abstract:`

			`Registry for format string reuse.`

			`Notes:`

			`This file defines reuse registry for format string fragments which may`
			`be reused later.`

			`History:`

			`Mar-14-1993 GregJen Created.`

			`----------------------------------------------------------------------------*/`

			`/****************************************************************************`
			`* include files`
			`***************************************************************************/`

			`#include "becls.hxx"`
			`#pragma hdrstop`

			`/***********************************************************************`
			`* global data`
			`**********************************************************************/`


			`FRMTREG_DICT::FRMTREG_DICT( FORMAT_STRING * pOurs)`
			`: Dictionary()`
			`{`
			`pOurFormatString = pOurs;`
			`}`

			`SSIZE_T`
			`FRMTREG_DICT::Compare( pUserType pL, pUserType pR )`
			`{`

			`FRMTREG_ENTRY * pLeft = (FRMTREG_ENTRY *) pL;`
			`FRMTREG_ENTRY * pRight = (FRMTREG_ENTRY *) pR;`

			`// first, sort by string length`

			`int Result = ( pLeft->EndOffset - pLeft->StartOffset ) -`
			`( pRight->EndOffset - pRight->StartOffset );`

			`if ( Result )`
			`return Result;`

			`long LeftOffset = pLeft->StartOffset;`
			`long RightOffset = pRight->StartOffset;`

			`unsigned char * pBuffer = pOurFormatString->pBuffer;`
			`unsigned char * pBufferType = pOurFormatString->pBufferType;`

			`// the same format string is, of course identical`
			`if ( LeftOffset == RightOffset )`
			`return 0;`

			`// There is a tricky situation when the strings are apart by more than 32k.`
			`// In the proc format string there is no problem with that, we can optize.`
			`// With type format string, we optimize as this is our best bet for the`
			`// final accessability of fragments.`

			`// Sort by values of format characters`

			`while ( ( Result == 0 ) && ( LeftOffset < pLeft->EndOffset) )`
			`{`

			`if ( pBufferType[ LeftOffset ] != pBufferType[ RightOffset ] )`
			`{`
			`// Types don't match, force the result to be unequal.`
			`Result = pBufferType[ LeftOffset ] - pBufferType[ RightOffset ];`
			`continue;`
			`}`

			`switch ( pBufferType[ LeftOffset ] )`
			`{`
			`case FS_SHORT_TYPE_OFFSET:`
			`// This is a comparison for the absolute type offset.`
			`{`
			`TypeOffsetDictElem pLeftTO, pRightTO;`

			`pLeftTO = pOurFormatString->TypeOffsetDict.`
			`LookupOffset( LeftOffset );`
			`pRightTO = pOurFormatString->TypeOffsetDict.`
			`LookupOffset( RightOffset );`

			`Result = pLeftTO->TypeOffset - pRightTO->TypeOffset;`

			`LeftOffset++; RightOffset++;`
			`}`
			`break;`

			`case FS_SHORT_OFFSET:`
			`// This is a comparison for the relative type offset.`
			`//`
			`{`
			`TypeOffsetDictElem pLeftTO, pRightTO;`

			`pLeftTO = pOurFormatString->TypeOffsetDict.`
			`LookupOffset( LeftOffset );`
			`pRightTO = pOurFormatString->TypeOffsetDict.`
			`LookupOffset( RightOffset );`

			`if ( ( pLeftTO->TypeOffset == 0 ) &&`
			`( pRightTO->TypeOffset == 0 ) )`
			`Result = 0;`
			`else`
			`// compare absolute offsets`
			`Result = ( LeftOffset + pLeftTO->TypeOffset ) -`
			`( RightOffset + pRightTO->TypeOffset );`

			`LeftOffset++; RightOffset++;`
			`}`
			`break;`

			`case FS_SHORT_STACK_OFFSET:`
			`// Compare stack offset - multiplatform issue.`
			`{`
			`Result = ((short UNALIGNED )(pBuffer + LeftOffset)) -`
			`((short UNALIGNED )(pBuffer + RightOffset));`

			`if ( Result == 0 )`
			`{`
			`BOOL f32bitServer = pCommand->Is32BitEnv();`

			`if ( f32bitServer )`
			`{`
			`OffsetDictElem pLeftStackOffsets, pRightStackOffsets;`

			`pLeftStackOffsets = pOurFormatString->OffsetDict.`
			`LookupOffset( LeftOffset );`
			`pRightStackOffsets = pOurFormatString->OffsetDict.`
			`LookupOffset( RightOffset );`

			`long Ilo = pLeftStackOffsets->X86Offset;`
			`long Iro = pRightStackOffsets->X86Offset;`
			`Result = Ilo - Iro;`
			`}`
			`}`

			`LeftOffset++; RightOffset++;`
			`}`
			`break;`

			`case FS_PAD_MACRO:`
			`case FS_SIZE_MACRO:`
			`case FS_UNKNOWN_STACK_SIZE:`
			`// Can't compare those, so force the result to be unequal.`
			`//`
			`Result = LeftOffset - RightOffset;`
			`break;`

			`case FS_LONG:`
			`// Compare longs`
			`//`
			`Result = ((long UNALIGNED )(pBuffer + LeftOffset)) -`
			`((long UNALIGNED )(pBuffer + RightOffset));`

			`LeftOffset += 3; RightOffset += 3;`
			`break;`

			`case FS_SHORT:`
			`case FS_PARAM_FLAG_SHORT:`
			`case FS_MAGIC_UNION_SHORT:`
			`case FS_CORR_FLAG_SHORT:`
			`// Compare plain shorts.`
			`//`
			`Result = ((short UNALIGNED )(pBuffer + LeftOffset)) -`
			`((short UNALIGNED )(pBuffer + RightOffset));`

			`LeftOffset++; RightOffset++;`
			`break;`

			`case FS_FORMAT_CHARACTER:`
			`case FS_POINTER_FORMAT_CHARACTER:`
			`case FS_SMALL:`
			`case FS_SMALL_STACK_SIZE:`
			`case FS_OLD_PROC_FLAG_BYTE:`
			`case FS_Oi2_PROC_FLAG_BYTE:`
			`case FS_EXT_PROC_FLAG_BYTE:`
			`case FS_CORR_TYPE_BYTE:`
			`case FS_CONTEXT_HANDLE_FLAG_BYTE:`
			`default:`
			`// Compare bytes, format chars, bytes decorated for comments,`
			`//`
			`Result = pBuffer[ LeftOffset ] - pBuffer[ RightOffset ];`
			`break;`
			`}`

			`LeftOffset++; RightOffset++;`
			`}`

			`return Result;`
			`}`


			`FRMTREG_ENTRY *`
			`FRMTREG_DICT::IsRegistered(`
			`FRMTREG_ENTRY * pInfo )`
			`/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++`

			`Routine Description:`

			`Search for a type with the reuse registry.`

			`Arguments:`

			`pInfo - A pointer to the type being registered.`

			`Return Value:`

			`The node that gets registered.`

			`Notes:`

			`----------------------------------------------------------------------------*/`
			`{`
			`Dict_Status Status = Dict_Find( pInfo );`

			`switch( Status )`
			`{`
			`case EMPTY_DICTIONARY:`
			`case ITEM_NOT_FOUND:`
			`return (FRMTREG_ENTRY *)0;`
			`default:`
			`return (FRMTREG_ENTRY *)Dict_Curr_Item();`
			`}`
			`}`

			`FRMTREG_ENTRY *`
			`FRMTREG_DICT::Register(`
			`FRMTREG_ENTRY * pInfo )`
			`/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++`

			`Routine Description:`

			`Register a type with the dictionary.`

			`Arguments:`

			`pType - A pointer to the type node.`

			`Return Value:`

			`The final inserted type.`

			`Notes:`

			`----------------------------------------------------------------------------*/`
			`{`
			`Dict_Insert( (pUserType) pInfo );`
			`return pInfo;`
			`}`

			`BOOL`
			`FRMTREG_DICT::GetReUseEntry(`
			`FRMTREG_ENTRY * & pOut,`
			`FRMTREG_ENTRY * pIn )`
			`/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++`

			`Routine Description:`

			`Register a type with the dictionary.`

			`Arguments:`

			`pRI - A pointer to the returned FRMTREG_ENTRY block`
			`pNode - A pointer to the type node.`

			`Return Value:`

			`True if the entry was already in the table,`
			`False if the entry is new.`

			`Notes:`

			`----------------------------------------------------------------------------*/`
			`{`
			`FRMTREG_ENTRY * pRealEntry;`

			`if ( ( pRealEntry = IsRegistered( pIn ) ) == 0 )`
			`{`
			`pRealEntry = new FRMTREG_ENTRY( pIn->StartOffset, pIn->EndOffset );`
			`Register( pRealEntry );`
			`pOut = pRealEntry;`
			`return FALSE;`
			`}`

			`pOut = pRealEntry;`
			`pOut->UseCount++;`
			`return TRUE;`
			`}`