737 lines
24 KiB
C++
737 lines
24 KiB
C++
//-------------------------------------------------------------------------
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//
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// Microsoft Windows
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// Copyright (C) Microsoft Corporation, 1992 - 1995
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//
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// File: caccess.cxx
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//
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// Contents: Microsoft OleDB/OleDS Data Source Object for ADSI
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//
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// CImpIAccessor object implementing the IAccessor interface.
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//
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// History: 10-01-96 shanksh Created.
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//-------------------------------------------------------------------------
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#include "oleds.hxx"
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#pragma hdrstop
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//-------------------------------------------------------------------------
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// CImpIAccessor::CImpIAccessor
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//
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// CImpIAccessor constructor.
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//
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//-------------------------------------------------------------------------
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CImpIAccessor::CImpIAccessor (
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void *pParentObj, //@parm IN | Parent object pointer
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LPUNKNOWN pUnkOuter //@parm IN | Outer Unknown pointer
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)
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{
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// Initialize simple member vars
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_pUnkOuter = pUnkOuter;
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_pObj = pParentObj;
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_pextbuffer = NULL;
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_dwStatus = 0;
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_pIDC = NULL;
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ENLIST_TRACKING(CImpIAccessor);
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// This section is for serializing &CreateAccessor.
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InitializeCriticalSection(&_criticalsectionAccessor);
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return;
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}
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//-------------------------------------------------------------------------
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// CImpIAccessor::~CImpIAccessor
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//
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// @mfunc CImpIAccessor destructor.
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//
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// @rdesc NONE
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//-------------------------------------------------------------------------
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CImpIAccessor::~CImpIAccessor (
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void
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)
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{
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ULONG_PTR hAccessor, hAccessorLast;
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PADSACCESSOR pADsaccessor, pADsaccessorBadHandle;
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// Cleanup only if there's anything to clean.
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if( _pextbuffer ) {
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// Get a pointer to the special "BadHandle" accessor.
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_pextbuffer->GetItemOfExtBuffer(hAccessorBadHandle, &pADsaccessorBadHandle);
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// Get the number of available accessor handles.
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_pextbuffer->GetLastItemHandle(hAccessorLast);
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// Loop through the reminding accessor handles deleting those which
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// are referenced only by this object and refcount decrementing the
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// other ones
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for (hAccessor =1; hAccessor <=hAccessorLast; hAccessor++) {
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// Get a pointer to the next accessor.
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_pextbuffer->GetItemOfExtBuffer(hAccessor, &pADsaccessor);
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// For valid accessors just delete them.
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if( pADsaccessor != pADsaccessorBadHandle )
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DeleteADsAccessor(pADsaccessor);
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}
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// Now delete the buffer which holds accessor handles.
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delete _pextbuffer;
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}
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if( _pIMalloc )
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_pIMalloc->Release();
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if( _pIDC )
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_pIDC->Release();
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// Get rid of the critical section.
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DeleteCriticalSection(&_criticalsectionAccessor);
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return;
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}
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//-------------------------------------------------------------------------
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// CImpIAccessor::FInit
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//
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// @mfunc Initialize the Accessor implementation object.
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//
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// @rdesc Did the Initialization Succeed
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// @flag S_OK initialization succeeded,
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// @flag E_OUTOFMEMORY initialization failed because of
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// memory allocation problem,
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//-------------------------------------------------------------------------
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STDMETHODIMP
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CImpIAccessor::FInit (
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void
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)
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{
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HRESULT hr;
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PADSACCESSOR pADsaccessorBadHandle;
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// Prepare a special, "Bad Handle" accessor.
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pADsaccessorBadHandle = (PADSACCESSOR)((BYTE *)&_dwGetDataTypeBadHandle);
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_dwGetDataTypeBadHandle = ACCESSORTYPE_INERROR;
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// Create the ExtBuffer array to hold pointers to malloc'd accessors.
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_pextbuffer = (LPEXTBUFF) new CExtBuff;
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if (_pextbuffer == NULL ||
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!(_pextbuffer->FInit(
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sizeof(PADSACCESSOR),
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&pADsaccessorBadHandle
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) ))
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RRETURN( E_OUTOFMEMORY );
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if( !_pIDC ) {
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hr = CoCreateInstance(
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CLSID_OLEDB_CONVERSIONLIBRARY,
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NULL,
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CLSCTX_INPROC_SERVER,
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IID_IDataConvert,
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(void **)&_pIDC
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);
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if ( FAILED(hr) ) {
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RRETURN (hr);
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}
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}
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hr = CoGetMalloc(MEMCTX_TASK, &_pIMalloc);
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RRETURN (hr);
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}
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//-------------------------------------------------------------------------
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// CImpIAccessor::AddRefAccessor
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//
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// @mfunc Adds a reference count to an existing accessor.
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//
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// @rdesc Did release of the accessor Succeed
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// @flag S_OK | accessor addrefed successfully,
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// @flag DB_E_BADACCESSORHANDLE | accessor could not be addrefed
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// because its handle was invalid.
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//-------------------------------------------------------------------------
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STDMETHODIMP CImpIAccessor::AddRefAccessor(
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HACCESSOR hAccessor, //@parm IN | handle of the accessor to release
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DBREFCOUNT *pcRefCounts //@parm OUT | count of references
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)
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{
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PADSACCESSOR pADsaccessor, pADsaccessorBadHandle;
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HRESULT hr;
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// Clear in case of error below.
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if( pcRefCounts )
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*pcRefCounts = 0;
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CAutoBlock cab( &(_criticalsectionAccessor) );
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// Get a pointer to the accessor.
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_pextbuffer->GetItemOfExtBuffer(hAccessor, &pADsaccessor);
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// Get a pointer to the special "BadHandle" accessor.
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_pextbuffer->GetItemOfExtBuffer(hAccessorBadHandle, &pADsaccessorBadHandle);
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// If the handle is valid
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if (pADsaccessor != pADsaccessorBadHandle) {
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if (pADsaccessor->cRef <= 0)
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BAIL_ON_FAILURE( hr = E_FAIL );
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pADsaccessor->cRef++;
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if (pcRefCounts)
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*pcRefCounts = pADsaccessor->cRef;
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RRETURN( S_OK );
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}
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// otherwise complain about a bad handle.
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else
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RRETURN( DB_E_BADACCESSORHANDLE );
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error:
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RRETURN( hr );
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}
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//-------------------------------------------------------------------------
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// CImpIAccessor::CreateAccessor
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//
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// @mfunc Creates an accessor, which is a set of bindings that can be used to
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// send data to or retrieve data from the data cache. The method performs
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// extensive validations on the input bindings which include verification of
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// the access type requested, column availability, data conversions involved,
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// etc.
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//
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// @rdesc Returns one of the following values:
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// S_OK | creation of the accessor succeeded,
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// E_INVALIDARG | creation of the accessor failed because
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// phAccessor was a NULL pointer,
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// E_OUTOFMEMORY | creation of the accessor failed because of
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// memory allocation problem,
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// DB_E_CANTCREATEACCESSOR | DBROWSETFLAGS_MULTIPLEACCESSOR flag was not
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// set and a row-fetching method has already
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// been called.
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// OTHER | other result codes returned by called functions.
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//-------------------------------------------------------------------------
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STDMETHODIMP CImpIAccessor::CreateAccessor(
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DBACCESSORFLAGS dwAccessorFlags,
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DBCOUNTITEM cBindings,
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const DBBINDING rgBindings[],
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DBLENGTH cbRowSize,
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HACCESSOR *phAccessor,
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DBBINDSTATUS rgStatus[]
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)
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{
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PADSACCESSOR pADsaccessor;
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ULONG_PTR hADsaccessor;
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HRESULT hr;
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ULONG dwGetDataType, dwSetDataType;
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DBCOUNTITEM ibind;
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BOOL fProviderOwned;
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DBBINDSTATUS bindstatus;
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ULONG wMask, wBaseType;
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if (phAccessor)
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*phAccessor = (HACCESSOR)0;
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// At the creation of the CAutoBlock object a critical section
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// is entered. Concurrent calls to CreateAccessor are entirely
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// legal but their interleaving cannot be allowed. The critical
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// section is left when this method terminate and the destructor
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// for CAutoBlock is called.
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CAutoBlock cab( &(_criticalsectionAccessor) );
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// phAccessor must never be NULL, non-zero bindings count implies a
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// non-NULL array of bindings.
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if( phAccessor == NULL || (cBindings && rgBindings == NULL) )
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RRETURN( E_INVALIDARG );
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// cBindings is 0 and was called on the Command.
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if( cBindings == 0 )
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RRETURN( DB_E_NULLACCESSORNOTSUPPORTED );
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// dwAccessorFlags cannot take any other values than those legal.
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if( dwAccessorFlags & (~DBACCESSOR_VALID_FLAGS) )
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RRETURN( DB_E_BADACCESSORFLAGS );
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// Compute internal types for use by methods using accessors,
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DetermineTypes(
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dwAccessorFlags,
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&dwGetDataType,
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&dwSetDataType
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);
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// and detect possible inconsistencies in AccessorFlags.
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if( dwGetDataType == GD_ACCESSORTYPE_INERROR ||
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dwSetDataType == SD_ACCESSORTYPE_INERROR )
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RRETURN( DB_E_BADACCESSORFLAGS );
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// fix conformance test failure. If BYREF accessors are not supported,
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// (indicated by DBPROP_BYREFACCESSORS being FALSE), we should return
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// the right error
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else if( (DB_E_BYREFACCESSORNOTSUPPORTED == dwGetDataType) ||
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(DB_E_BYREFACCESSORNOTSUPPORTED == dwSetDataType) )
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RRETURN( DB_E_BYREFACCESSORNOTSUPPORTED );
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// Initialize the status array to DBBINDSTATUS_OK.
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if( rgStatus )
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memset(rgStatus, 0x00, (size_t)(cBindings*sizeof(DBBINDSTATUS)));
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hr = S_OK;
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fProviderOwned = FALSE;
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// Perform validations that apply to all types of accessors.
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for (ibind=0; ibind < cBindings; ibind++) {
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bindstatus = DBBINDSTATUS_OK;
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if( rgBindings[ibind].dwMemOwner != DBMEMOWNER_PROVIDEROWNED &&
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rgBindings[ibind].dwMemOwner != DBMEMOWNER_CLIENTOWNED )
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bindstatus = DBBINDSTATUS_BADBINDINFO;
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// The part to be bound must specify one or more out of three values, and
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if( (rgBindings[ibind].dwPart &
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(DBPART_VALUE |DBPART_LENGTH |DBPART_STATUS)) == 0 ||
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// nothing else.
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(rgBindings[ibind].dwPart &
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~(DBPART_VALUE |DBPART_LENGTH |DBPART_STATUS)) ||
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// Is it a good type to bind to?
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!IsGoodBindingType(rgBindings[ibind].wType) )
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bindstatus = DBBINDSTATUS_BADBINDINFO;
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// DBTYPE_BYREF, DBTYPE_VECTOR and DBTYPE_ARRAY cannot be combined.
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else if( (wMask = (rgBindings[ibind].wType & TYPE_MODIFIERS)) &&
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wMask != DBTYPE_BYREF &&
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wMask != DBTYPE_VECTOR &&
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wMask != DBTYPE_ARRAY )
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bindstatus = DBBINDSTATUS_BADBINDINFO;
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else if ((wBaseType = (rgBindings[ibind].wType & ~TYPE_MODIFIERS)) ==
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DBTYPE_EMPTY ||
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wBaseType == DBTYPE_NULL)
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bindstatus = DBBINDSTATUS_BADBINDINFO;
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// DBTYPE_ARRAY and DBTYPE_VECTOR are not supported types
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else if( (rgBindings[ibind].wType & DBTYPE_ARRAY) ||
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(rgBindings[ibind].wType & DBTYPE_VECTOR) )
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bindstatus = DBBINDSTATUS_UNSUPPORTEDCONVERSION;
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// dwFlags was DBBINDFLAG_HTML and the type was not a String
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else if ( rgBindings[ibind].dwFlags &&
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(rgBindings[ibind].dwFlags != DBBINDFLAG_HTML ||
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(wBaseType != DBTYPE_STR &&
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wBaseType != DBTYPE_WSTR &&
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wBaseType != DBTYPE_BSTR)) )
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{
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// Set Bind status to DBBINDSTATUS_BADBINDINFO
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bindstatus = DBBINDSTATUS_BADBINDINFO;
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}
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else if( rgBindings[ibind].wType == (DBTYPE_RESERVED | DBTYPE_BYREF) )
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bindstatus = DBBINDSTATUS_BADBINDINFO;
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else if( rgBindings[ibind].dwMemOwner == DBMEMOWNER_PROVIDEROWNED ) {
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if( (rgBindings[ibind].wType & TYPE_MODIFIERS) == 0
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&& rgBindings[ibind].wType != DBTYPE_BSTR )
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bindstatus = DBBINDSTATUS_BADBINDINFO;
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else
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fProviderOwned = TRUE;
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}
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if( bindstatus != DBBINDSTATUS_OK )
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hr = DB_E_ERRORSOCCURRED;
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if( rgStatus )
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rgStatus[ibind] = bindstatus;
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}
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// Check for errors in the bindings
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BAIL_ON_FAILURE( hr );
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if( fProviderOwned &&
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(dwGetDataType == GD_ACCESSORTYPE_READ ||
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dwGetDataType == GD_ACCESSORTYPE_READ_OPTIMIZED) )
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dwGetDataType = GD_ACCESSORTYPE_READ_COLS_BYREF;
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// Allocate space for the accessor structure.
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pADsaccessor = (ADSACCESSOR *) new BYTE
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[(size_t)(sizeof(ADSACCESSOR) + (cBindings ? (cBindings-1) : 0)*
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sizeof(DBBINDING))];
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if( pADsaccessor == NULL )
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RRETURN( E_OUTOFMEMORY );
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if( cBindings )
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memcpy(
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&(pADsaccessor->rgBindings[0]),
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&rgBindings[0],
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(size_t)(cBindings*sizeof(DBBINDING))
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);
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pADsaccessor->cBindings = cBindings;
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// For accessors valid for writing fill out a list of columns
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// so that notifications about their changes can be properly issued.
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if( dwSetDataType == SD_ACCESSORTYPE_READWRITE && cBindings ) {
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pADsaccessor->rgcol = new DBORDINAL [ (size_t)cBindings ];
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if( pADsaccessor->rgcol == NULL ) {
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dwSetDataType = SD_ACCESSORTYPE_INERROR;
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}
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else
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for (ibind =0; ibind <cBindings; ibind++)
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(pADsaccessor->rgcol)[ibind] = rgBindings[ibind].iOrdinal;
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}
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else
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pADsaccessor->rgcol = NULL;
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// Allocate DBOBJECT structures supporting IUnknown types.
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for (ibind =0; ibind <cBindings; ibind++)
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pADsaccessor->rgBindings[ibind].pObject = NULL;
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// Set accessor flags now, so that possible accessor cleanup routine would
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// know about additional structures for IUnknown types support.
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pADsaccessor->dwFlags = dwAccessorFlags;
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// Insert the new accessor pointer into the extensible buffer in which
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// accessors are stored.
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if( FAILED(hr = _pextbuffer->InsertIntoExtBuffer(
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&pADsaccessor,
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hADsaccessor
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)) ) {
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DeleteADsAccessor(pADsaccessor);
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RRETURN (hr);
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}
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pADsaccessor->cRef = 1;
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// Fill out the new accessor structure with the binding info.
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//pADsaccessor->obRowData = obRowData;
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pADsaccessor->cbRowSize = cbRowSize;
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// Return the accessor index in the extensible buffer as the accessor
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// handle.
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*phAccessor = (HACCESSOR) hADsaccessor;
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// Now can safely leave.
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RRETURN( NOERROR );
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error:
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RRETURN( hr );
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}
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//-------------------------------------------------------------------------
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// CImpIAccessor::DetermineTypes
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//
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// @mfunc Determines internal accessor type classification for use by GetData,
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// SetData and parameter handling code. Each of these has a separate type indicator
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// variable and a separate set of defined types. This allows a very efficient
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// handling of different accessors by methods that utilize them.
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// Types are determined on the basis of AccessorFlags. Incorrect combinations of
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// flags result in assignment of INERROR types.
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//
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// @rdesc NONE
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//-------------------------------------------------------------------------
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STDMETHODIMP_(void)
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CImpIAccessor::DetermineTypes(
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DBACCESSORFLAGS dwAccessorFlags,
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ULONG *pdwGetDataType,
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ULONG *pdwSetDataType
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)
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{
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if( dwAccessorFlags & DBACCESSOR_PASSBYREF )
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{
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*pdwGetDataType = (ULONG) DB_E_BYREFACCESSORNOTSUPPORTED;
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*pdwSetDataType = (ULONG) DB_E_BYREFACCESSORNOTSUPPORTED;
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return;
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}
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else if( dwAccessorFlags & DBACCESSOR_PARAMETERDATA )
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{
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*pdwGetDataType = GD_ACCESSORTYPE_INERROR;
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*pdwSetDataType = GD_ACCESSORTYPE_INERROR;
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return;
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}
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// Determine types used in row data manipulations.
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if( dwAccessorFlags & DBACCESSOR_ROWDATA ) {
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// Determine accessor type from the point of
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// view of GetData.
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if( dwAccessorFlags & DBACCESSOR_OPTIMIZED )
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*pdwGetDataType = GD_ACCESSORTYPE_READ_OPTIMIZED;
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else
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*pdwGetDataType = GD_ACCESSORTYPE_READ;
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// Determine accessor type from the point of
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// view of SetData. PASSBYREF is disallowed.
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*pdwSetDataType = SD_ACCESSORTYPE_READWRITE;
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}
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else {
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*pdwGetDataType = GD_ACCESSORTYPE_INERROR;
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*pdwSetDataType = GD_ACCESSORTYPE_INERROR;
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}
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return;
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}
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//-------------------------------------------------------------------------
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// CImpIAccessor::GetBindings
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//
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// @mfunc Returns bindings of an accessor.
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//
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// @rdesc Returns one of the following values:
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// S_OK | getting bindings succeeded,
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// E_INVALIDARG | getting bindings failed because
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// pdwAccessorFlags or pcBindings or
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// prgBindings was a NULL pointer,
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// E_OUTOFMEMORY | getting bindings failed because memory
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// allocation for the bindings array failed,
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// OTHER | other result codes stored on the accessor
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// object and singifying invalid accessor handle.
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//-------------------------------------------------------------------------
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STDMETHODIMP CImpIAccessor::GetBindings
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(
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HACCESSOR hAccessor, // IN | accessor handle
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DBACCESSORFLAGS *pdwAccessorFlags, // OUT | stores accessor flags
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DBCOUNTITEM *pcBindings, // OUT | stores # of bindings
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DBBINDING **prgBindings // OUT | stores array of bindings
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)
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{
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PADSACCESSOR pADsaccessor;
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PADSACCESSOR pADsaccessorBadHandle;
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DBCOUNTITEM ibind;
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DBOBJECT *pObject;
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if( pcBindings )
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*pcBindings = 0;
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if( prgBindings )
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*prgBindings = NULL;
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if( pdwAccessorFlags )
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*pdwAccessorFlags = DBACCESSOR_INVALID;
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// Are arguments valid?
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if( pdwAccessorFlags == NULL || pcBindings == NULL || prgBindings == NULL )
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RRETURN( E_INVALIDARG );
|
|
|
|
// Obtain pointer to the accessor to be used.
|
|
_pextbuffer->GetItemOfExtBuffer(hAccessor, &pADsaccessor);
|
|
|
|
// Get a pointer to the special "BadHandle" accessor.
|
|
_pextbuffer->GetItemOfExtBuffer(hAccessorBadHandle, &pADsaccessorBadHandle);
|
|
|
|
// Recognize bad accessor handles and return appropriate HRESULT.
|
|
if( pADsaccessor == pADsaccessorBadHandle )
|
|
return DB_E_BADACCESSORHANDLE;
|
|
|
|
// If necessary allocate the array of binding structures.
|
|
if( pADsaccessor->cBindings ) {
|
|
*prgBindings = (DBBINDING *) _pIMalloc->Alloc((ULONG)(
|
|
pADsaccessor->cBindings*sizeof(DBBINDING) ));
|
|
|
|
if( *prgBindings == NULL )
|
|
RRETURN ( E_OUTOFMEMORY );
|
|
|
|
// Copy bindings.
|
|
memcpy(
|
|
*prgBindings,
|
|
pADsaccessor->rgBindings,
|
|
(size_t)(pADsaccessor->cBindings*sizeof(DBBINDING))
|
|
);
|
|
|
|
// Loop through bindings and allocate and copy DBOBJECT structs.
|
|
for (ibind=0; ibind <pADsaccessor->cBindings; ibind++) {
|
|
// If the accessor had failed bindings for SetData, we have
|
|
// overloaded an unused structure member with status info, and
|
|
// this needs to be cleaned now.
|
|
(*prgBindings)[ibind].pTypeInfo = NULL;
|
|
|
|
if( (*prgBindings)[ibind].pObject ) {
|
|
pObject = (DBOBJECT *) _pIMalloc->Alloc( sizeof(DBOBJECT) );
|
|
if( pObject ) {
|
|
memcpy(
|
|
pObject,
|
|
(*prgBindings)[ibind].pObject,
|
|
sizeof(DBOBJECT)
|
|
);
|
|
(*prgBindings)[ibind].pObject = pObject;
|
|
}
|
|
else {
|
|
while (ibind--)
|
|
if( (*prgBindings)[ibind].pObject )
|
|
_pIMalloc->Free((*prgBindings)[ibind].pObject);
|
|
|
|
_pIMalloc->Free( *prgBindings );
|
|
*prgBindings = NULL;
|
|
RRETURN( E_OUTOFMEMORY );
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
// Return the count of bindings,
|
|
*pcBindings = pADsaccessor->cBindings;
|
|
// and accessor flags.
|
|
*pdwAccessorFlags = (pADsaccessor->dwFlags & ~DBACCESSOR_REFERENCES_BLOB);
|
|
|
|
return S_OK;
|
|
}
|
|
|
|
|
|
|
|
//-------------------------------------------------------------------------
|
|
// CImpIAccessor::ReleaseAccessor
|
|
//
|
|
// @mfunc Releases accessor. If accessor handle is valid the corresponding accessor
|
|
// is either freed (if no one else is using it) or its ref count is decremented.
|
|
//
|
|
// @rdesc Did release of the accessor Succeed
|
|
// @flag S_OK | accessor released successfully,
|
|
// @flag DB_E_BADACCESSORHANDLE | accessor could not be released because its
|
|
// | handle was invalid.
|
|
//-------------------------------------------------------------------------
|
|
|
|
STDMETHODIMP CImpIAccessor::ReleaseAccessor
|
|
(
|
|
HACCESSOR hAccessor, //@parm IN | handle of the accessor to release
|
|
DBREFCOUNT *pcRefCounts //@parm OUT | ref count of the released accessor
|
|
)
|
|
{
|
|
PADSACCESSOR pADsaccessor, pADsaccessorBadHandle;
|
|
|
|
if( pcRefCounts )
|
|
*pcRefCounts = 0;
|
|
|
|
CAutoBlock cab( &(_criticalsectionAccessor) );
|
|
|
|
// Get a pointer to the accessor.
|
|
_pextbuffer->GetItemOfExtBuffer(hAccessor, &pADsaccessor);
|
|
|
|
// Get a pointer to the special "BadHandle" accessor.
|
|
_pextbuffer->GetItemOfExtBuffer(hAccessorBadHandle, &pADsaccessorBadHandle);
|
|
|
|
// If the handle is valid
|
|
if( pADsaccessor != pADsaccessorBadHandle ) {
|
|
ADsAssert(pADsaccessor->cRef > 0);
|
|
|
|
// Delete if no one else is using it, otherwise
|
|
if( pADsaccessor->cRef == 1 ) {
|
|
// Delete the accessor structure itself, as well as allocations
|
|
// hanging off this structure.
|
|
DeleteADsAccessor(pADsaccessor);
|
|
|
|
// Make sure this handle is marked as "Bad" for future.
|
|
_pextbuffer->DeleteFromExtBuffer(hAccessor);
|
|
}
|
|
// decrement the refcount.
|
|
else {
|
|
pADsaccessor->cRef--;
|
|
|
|
if( pcRefCounts )
|
|
*pcRefCounts = pADsaccessor->cRef;
|
|
}
|
|
|
|
return NOERROR;
|
|
}
|
|
// otherwise complain about a bad handle.
|
|
else
|
|
RRETURN( DB_E_BADACCESSORHANDLE );
|
|
}
|
|
|
|
//-------------------------------------------------------------------------
|
|
// CImpIAccessor::DeleteADsAccessor
|
|
//
|
|
// @mfunc Deletes structures hanging off the ADSACCESSOR and then deletes the
|
|
// accessor structure itself.
|
|
//
|
|
// @rdesc NONE
|
|
//-------------------------------------------------------------------------
|
|
|
|
STDMETHODIMP_(void) CImpIAccessor::DeleteADsAccessor
|
|
(
|
|
PADSACCESSOR pADsaccessor //@parm IN | Kagera accessor ptr
|
|
)
|
|
{
|
|
DBCOUNTITEM ibind;
|
|
|
|
// Delete the list of affected columns.
|
|
if( pADsaccessor->rgcol )
|
|
delete [] pADsaccessor->rgcol;
|
|
|
|
// If the accessor references BLOBS then DBOBJECT structures describing
|
|
// objects dealing with BLOBS need to be deallocated.
|
|
for (ibind =0; ibind <pADsaccessor->cBindings; ibind++)
|
|
if( pADsaccessor->rgBindings[ibind].pObject )
|
|
delete pADsaccessor->rgBindings[ibind].pObject;
|
|
|
|
delete [] pADsaccessor;
|
|
}
|
|
|
|
|
|
STDMETHODIMP
|
|
CImpIAccessor::QueryInterface(REFIID iid, LPVOID FAR* ppv)
|
|
{
|
|
// Is the pointer bad?
|
|
if( ppv == NULL )
|
|
RRETURN( E_INVALIDARG );
|
|
|
|
// Place NULL in *ppv in case of failure
|
|
*ppv = NULL;
|
|
|
|
if( IsEqualIID(iid, IID_IUnknown) ) {
|
|
*ppv = (IAccessor FAR *) this;
|
|
}
|
|
else if( IsEqualIID(iid, IID_IAccessor) ) {
|
|
*ppv = (IAccessor FAR *) this;
|
|
}
|
|
else {
|
|
RRETURN( E_NOINTERFACE );
|
|
}
|
|
|
|
AddRef();
|
|
return S_OK;
|
|
}
|
|
|
|
//---------------------------------------------------------------------------
|
|
// CreateBadAccessor
|
|
//
|
|
// Inserts a bad accessor into the array of accessors (indexed by accessor
|
|
// handles). This is required so that inheritance of accessors from commands
|
|
// works correctly. If there are any 'holes' in the command's array of
|
|
// accessors, then a rowset created from the command should also inherit these
|
|
// 'holes' i,e, the array of accessor handles should not be compacted to
|
|
// eliminate these holes. This is done using this function.
|
|
//
|
|
//---------------------------------------------------------------------------
|
|
HRESULT
|
|
CImpIAccessor::CreateBadAccessor(void)
|
|
{
|
|
PADSACCESSOR pADsaccessorBadHandle;
|
|
ULONG_PTR hADsaccessor;
|
|
HRESULT hr;
|
|
|
|
// Get a pointer to the special "BadHandle" accessor.
|
|
_pextbuffer->GetItemOfExtBuffer(hAccessorBadHandle, &pADsaccessorBadHandle);
|
|
|
|
// ignore the returned accessor handle
|
|
hr = _pextbuffer->InsertIntoExtBuffer(
|
|
&pADsaccessorBadHandle, hADsaccessor);
|
|
|
|
RRETURN( hr );
|
|
}
|
|
|
|
//---------------------------------------------------------------------------
|
|
|
|
|
|
|
|
|