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使用大數值類型

在 SQL Server 2005 之前,使用大數值資料類型時需要進行特殊處理。 大數值資料類型是指那些最大資料列大小超過 8 KB 的資料類型。 SQL Server 2005 推出了 max 規範,這個規範可用於 varcharnvarcharvarbinary 資料類型,以允許儲存最大可達 2^31 -1 個位元組的值。 資料表資料行和 Transact-SQL 變數可以指定 varchar(max)nvarchar(max)varbinary(max) 資料類型。

[!附註]

大數值資料類型的最大大小可介於 1 和 8 KB 之間,或者也可以指定為無限制。

先前,只有 textntextimage 之類的 SQL Server 資料類型可以達到此種長度。 varcharnvarcharvarbinarymax 規範使這些資料類型變得多餘。 不過,因為 long 資料類型仍可使用,所以大部分 OLE DB 和 ODBC 資料存取元件的介面都仍保持原樣。 為了與先前的版本保持回溯相容性,SQL Server Native Client OLE DB 提供者中的 DBCOLUMNFLAGS_ISLONG 旗標以及 SQL Server Native Client ODBC 驅動程式中的 SQL_LONGVARCHAR 仍會繼續使用。 當新類型設定為無限制的最大長度時,針對 SQL Server 2005 和更新版本所撰寫的提供者和驅動程式仍會為其繼續使用這些詞彙。

[!附註]

您也可以將 varchar(max)nvarchar(max)varbinary(max) 資料類型指定為預存程序的輸入和輸出參數類型、函數傳回類型,或者指定於 CAST 和 CONVERT 函數。

[!附註]

如果複寫資料,您可能需要將 max text repl size 伺服器組態選項設定為 -1。

SQL Server Native Client OLE DB 提供者

SQL Server Native Client OLE DB 提供者會將 varchar(max)varbinary(max)nvarchar(max) 類型分別公開為 DBTYPE_STR、DBTYPE_BYTES 和 DBTYPE_WSTR。

max 大小設定為無限制的資料行中,varchar(max)varbinary(max)nvarchar(max) 資料類型會在傳回資料行資料類型的核心 OLE DB 結構描述資料列集和介面中表示為 ISLONG。

命令物件的 IAccessor 實作已變更為允許以 DBTYPE_IUNKNOWN 的形式進行繫結。 如果取用者指定 DBTYPE_IUNKNOWN 並將 pObject 設定為 null,則提供者會將 ISequentialStream 介面傳回給取用者,讓取用者可以將 varchar(max)nvarchar(max)varbinary(max) 用資料流的形式傳出輸出變數。

以資料流傳輸的輸出參數值會在任何結果資料列之後傳回。 如果應用程式藉由呼叫 IMultipleResults::GetResult (而不取用所有的傳回輸出參數值) 嘗試繼續前往下一個結果集,就會傳回 DB_E_OBJECTOPEN。

為了支援資料流作業,SQL Server Native Client OLE DB 提供者需要循序存取可變長度的參數。 這表示每當 varchar(max)nvarchchar(max)varbinary(max) 資料行或輸出參數繫結至 DBTYPE_IUNKNOWN 時,DBPROP_ACCESSORDER 就必須設定為 DBPROPVAL_AO_SEQUENTIALSTORAGEOBJECTS 或 DBPROPVAL_AO_SEQUENTIAL。 如果未遵守這項存取順序的限制,則對 IRowset::GetData 的呼叫會失敗,且傳回 DBSTATUS_E_UNAVAILABLE。 當沒有任何使用 DBTYPE_IUNKNOWN 的輸出繫結時,這項限制就不適用。

SQL Server Native Client OLE DB 提供者也支援將輸出參數針對大數值資料類型而繫結為 DBTYPE_IUNKNOWN,這在預存程序要將大數值類型以傳回值 (對用戶端公開為 DBTYPE_IUNKNOWN) 傳回時很有用。

為了使用這些類型,應用程式具有下列選項:

  • 繫結為具有資料行基底類型所支援繫結的類型 (例如,對於 nvarchar(max),繫結為可繫結到 nvarchar 的類型)。 如果緩衝區不夠大,就會進行截斷,這與基底類型完全相同,只是現在使用的是較大數值。

  • 繫結為具有資料行基底類型所支援轉換的類型,並同時指定 DBTYPE_BYREF。

  • 繫結為 DBTYPE_IUNKNOWN 並使用資料流。

在報告資料行的最大大小時,SQL Server Native Client OLE DB 提供者會報告:

  • 定義的最大大小,例如 varchar(2000) 資料行的最大大小為 2000,或者

  • "unlimited" 這個值,如果是 varchar(max) 資料行則等於 0。 這個值會針對 DBCOLUMN_COLUMNSIZE 中繼資料屬性設定。

標準轉換規則適用於 varchar(max) 資料行,代表任何對 varchar(2000) 資料行有效的轉換也對 varchar(max) 資料行有效。 相同的規則也適用於 nvarchar(max)varbinary(max) 資料行。

在擷取大數值類型時,最有效的方法是繫結為 DBTYPE_IUNKNOWN,並將資料列集屬性 DBPROP_ACCESSORDER 設定為 DBPROPVAL_AO_SEQUENTIALSTORAGEOBJECTS。 這樣會導致數值直接從網路以資料流的方式傳出,而不必經過中間的緩衝作業,如下列範例所示:

#define UNICODE
#define _UNICODE
#define DBINITCONSTANTS
#define INITGUID
#define OLEDBVER 0x0250  // To include the correct interfaces.

#include <stdio.h>
#include <tchar.h>
#include <stddef.h>
#include <iostream>

using std::cout;
using std::endl;

#include <windows.h>

#include <oledb.h>
#include "sqlncli.h"
#include <oledberr.h>

#define CHKHR_GOTO(hr, errMsg, Label) \
   if (FAILED(hr)) \
   { \
      cout << errMsg << endl; \
      goto Label; \
   }

#define MAX_COL_SIZE 8000

// ROUNDUP on all platforms pointers must be aligned properly.
#define ROUNDUP_AMOUNT 8
#define ROUNDUP_(size,amount) (((ULONG)(size)+((amount)-1))&~((amount)-1))
#define ROUNDUP(size) ROUNDUP_(size, ROUNDUP_AMOUNT)

HRESULT InitializeAndEstablishConnection(IDBInitialize** ppIDBInitialize);
void UnInitializeConnection(IDBInitialize* pIDBInitialize);
HRESULT CreateAndSetCommand(IDBInitialize* pIDBInitialize, ICommandText** ppICommandText);
HRESULT ProcessResultSet(IRowset* pIRowset);

void DisplayTime()
{
   SYSTEMTIME st;
   GetSystemTime(&st);
   cout<< st.wHour << ":" << st.wMinute << ":" << st.wSecond << "." << st.wMilliseconds << endl;
}

void main()
{
   HRESULT hr;
   IDBInitialize* pIDBInitialize = NULL;
   ICommandText* pICommandText = NULL;
   IMultipleResults* pIMultipleResults = NULL;
   IRowset* pIRowset = NULL;

   hr = InitializeAndEstablishConnection(&pIDBInitialize);
   CHKHR_GOTO(hr, L"Failed to establish connection.", _ExitMain);

   hr = CreateAndSetCommand(pIDBInitialize, &pICommandText);
   CHKHR_GOTO(hr, L"Failed to set up command object.", _ExitMain);

   DisplayTime();

   hr = pICommandText->Execute(NULL, 
      IID_IMultipleResults, 
      NULL, 
      NULL, 
     (IUnknown **) &pIMultipleResults);

   CHKHR_GOTO(hr, L"Failed to execute command.", _ExitMain);

   while (1)
   {
      hr = pIMultipleResults->GetResult(
         NULL, 
         DBRESULTFLAG_DEFAULT, 
         IID_IRowset, 
         NULL, 
         (IUnknown**)&pIRowset);

   CHKHR_GOTO(hr, L"Failed to obtain a results from MR object.", _ExitMain);

   if (hr == DB_S_NORESULT)
      break;

      if (pIRowset)
      {
         hr = ProcessResultSet(pIRowset); 
         CHKHR_GOTO(hr, L"Failed to process the current Rowset.", _ExitMain);

         pIRowset->Release();
         pIRowset = NULL;
      }
   }

   DisplayTime();

_ExitMain:

   if (pIRowset)
   {
      pIRowset->Release();
      pIRowset = NULL;
   }

   if (pIMultipleResults)
   {
      pIMultipleResults->Release();
      pIMultipleResults = NULL;
   }

   if (pICommandText)
   {
      pICommandText->Release();
      pICommandText = NULL;
   }

   UnInitializeConnection(pIDBInitialize);
   return;
};

HRESULT InitializeAndEstablishConnection(IDBInitialize** ppIDBInitialize)
{
   HRESULT hr;
   IDBInitialize* pIDBInitialize = NULL;
   IDBProperties* pIDBProperties = NULL;

   const int NUM_DBINIT_PROPS = 3;
   const wchar_t* const g_wszServer = L".";
   const wchar_t* const g_wszCatalog = L"AdventureWorks";
   const wchar_t* const g_wszSecurity = L"SSPI";

   DBPROPSET rgdbPropSetInit[1];
   DBPROP rgdbPropInit [NUM_DBINIT_PROPS];

   *ppIDBInitialize = NULL;
   hr = CoInitialize(NULL);
   CHKHR_GOTO(hr, L"Failed to initialize COM.", _ExitInitialize);

   hr = CoCreateInstance(CLSID_SQLNCLI11, 
      NULL, 
      CLSCTX_INPROC_SERVER,
      IID_IDBInitialize, 
      (void**)&pIDBInitialize);

   CHKHR_GOTO(hr, L"Failed to create SQLNCLI11 DataSource object.", _ExitInitialize);

   for(int idxProp = 0; idxProp < NUM_DBINIT_PROPS; idxProp++) 
   {
      VariantInit(&rgdbPropInit[idxProp].vValue);
   }

   rgdbPropInit[0].dwPropertyID = DBPROP_INIT_DATASOURCE;
   rgdbPropInit[0].vValue.vt = VT_BSTR;
   rgdbPropInit[0].vValue.bstrVal= SysAllocString(g_wszServer);
   rgdbPropInit[0].dwOptions = DBPROPOPTIONS_REQUIRED;
   rgdbPropInit[0].colid = DB_NULLID;

   if (rgdbPropInit[0].vValue.bstrVal == NULL)
   {
      hr = E_OUTOFMEMORY;
      goto _ExitInitialize;
   }

   rgdbPropInit[1].dwPropertyID = DBPROP_INIT_CATALOG;
   rgdbPropInit[1].vValue.vt = VT_BSTR;
   rgdbPropInit[1].vValue.bstrVal= SysAllocString(g_wszCatalog);
   rgdbPropInit[1].dwOptions = DBPROPOPTIONS_REQUIRED;
   rgdbPropInit[1].colid = DB_NULLID;

   if (rgdbPropInit[1].vValue.bstrVal == NULL)
   {
      hr = E_OUTOFMEMORY;
      goto _ExitInitialize;
   }

   rgdbPropInit[2].dwPropertyID = DBPROP_AUTH_INTEGRATED;
   rgdbPropInit[2].vValue.vt = VT_BSTR;
   rgdbPropInit[2].vValue.bstrVal= SysAllocString(g_wszSecurity);
   rgdbPropInit[2].dwOptions = DBPROPOPTIONS_REQUIRED;
   rgdbPropInit[2].colid = DB_NULLID;

   if (rgdbPropInit[2].vValue.bstrVal == NULL)
   {
      hr = E_OUTOFMEMORY;
      goto _ExitInitialize;
   }

   rgdbPropSetInit[0].guidPropertySet = DBPROPSET_DBINIT;
   rgdbPropSetInit[0].cProperties = NUM_DBINIT_PROPS;
   rgdbPropSetInit[0].rgProperties = rgdbPropInit;

   hr = pIDBInitialize->QueryInterface(IID_IDBProperties, (void **)&pIDBProperties);
   CHKHR_GOTO(hr, L"Failed to QI DataSource object for IDBProperties.", _ExitInitialize);

   hr = pIDBProperties->SetProperties(1, rgdbPropSetInit); 
   CHKHR_GOTO(hr, L"Failed to set DataSource object Properties.", _ExitInitialize);

   pIDBProperties->Release();
   pIDBProperties = NULL;

   hr = pIDBInitialize->Initialize();
   CHKHR_GOTO(hr, L"Failed to establish connection with the server.", _ExitInitialize);

_ExitInitialize:

   if (pIDBProperties)
   {
      pIDBProperties->Release();
      pIDBProperties = NULL;
   }

   if (FAILED(hr))
   {
      if (pIDBInitialize)
      {
         pIDBInitialize->Release();
         pIDBInitialize = NULL;
      }
   }

   *ppIDBInitialize = pIDBInitialize;
   return hr;
}

void UnInitializeConnection(IDBInitialize* pIDBInitialize)
{
   if (pIDBInitialize)
   {
      pIDBInitialize->Uninitialize();
      pIDBInitialize->Release();
      pIDBInitialize = NULL;
   }
   CoUninitialize();
}

HRESULT CreateAndSetCommand(IDBInitialize* pIDBInitialize, ICommandText** ppICommandText)
{
   HRESULT hr;
   IDBCreateSession* pIDBCreateSession = NULL;
   IDBCreateCommand* pIDBCreateCommand = NULL;
   ICommandText* pICommandText = NULL;
   ICommandProperties* pICommandProperties = NULL;
   DBPROPSET rgCmdPropSet[1];
   DBPROP rgCmdProperties[1];

const wchar_t* const g_wCmdString = L"declare @x xml, @y nvarchar(max); select @x = (SELECT * FROM Sales.SalesOrderHeader FOR XML AUTO); select @x;";

   *ppICommandText = NULL;

   if (!pIDBInitialize)
   {
      hr = E_FAIL;
      goto _ExitCreateAndSetCommand;
   }

   hr = pIDBInitialize->QueryInterface(IID_IDBCreateSession, (void**) &pIDBCreateSession);
   CHKHR_GOTO(hr, L"Failed to obtain IDBCreateSession interface from DSO.", _ExitCreateAndSetCommand);

   hr = pIDBCreateSession->CreateSession(
      NULL, 
      IID_IDBCreateCommand, 
      (IUnknown**) &pIDBCreateCommand);

   CHKHR_GOTO(hr, L"Failed to Create a Session for command execution.", _ExitCreateAndSetCommand);

   hr = pIDBCreateCommand->CreateCommand(
      NULL, 
      IID_ICommandText, 
      (IUnknown**)&pICommandText);

   CHKHR_GOTO(hr, L"Failed to Create a Command object.", _ExitCreateAndSetCommand);

   hr = pICommandText->SetCommandText(DBGUID_DBSQL, g_wCmdString);
   CHKHR_GOTO(hr, L"Failed to Set Command Text.", _ExitCreateAndSetCommand);

   hr = pICommandText->QueryInterface(IID_ICommandProperties, (void**) &pICommandProperties);
   CHKHR_GOTO(hr, L"Failed to obtain ICommandProperties interface from the command object.", _ExitCreateAndSetCommand);

   rgCmdProperties[0].dwPropertyID = DBPROP_ACCESSORDER;
   rgCmdProperties[0].vValue.vt = VT_I4;
   rgCmdProperties[0].vValue.lVal = DBPROPVAL_AO_SEQUENTIAL;
   rgCmdProperties[0].dwOptions = DBPROPOPTIONS_REQUIRED;
   rgCmdProperties[0].colid = DB_NULLID;

   rgCmdPropSet[0].guidPropertySet = DBPROPSET_ROWSET;
   rgCmdPropSet[0].cProperties = 1;
   rgCmdPropSet[0].rgProperties = rgCmdProperties;

   hr = pICommandProperties->SetProperties(1, rgCmdPropSet); 
   CHKHR_GOTO(hr, L"Failed to Set Command object Properties.", _ExitCreateAndSetCommand);

_ExitCreateAndSetCommand:

   if (pICommandProperties)
   {
      pICommandProperties->Release();
      pICommandProperties = NULL;
   }

   if (pIDBCreateCommand)
   {
      pIDBCreateCommand->Release();
      pIDBCreateCommand = NULL;
   }

   if (pIDBCreateSession)
   {
      pIDBCreateSession->Release();
      pIDBCreateSession = NULL;
   }

   if (FAILED(hr))
   {
      if (pICommandText)
      {
         pICommandText->Release();
         pICommandText = NULL;
      }
   }

   *ppICommandText = pICommandText;
   return hr;
}

HRESULT ProcessResultSet(IRowset* pIRowset)
{
   HRESULT hr;

   IColumnsInfo* pIColumnsInfo = NULL;
   DBCOLUMNINFO* pDBColumnInfo = NULL;
   ULONG lNumCols = 0;
   wchar_t* pStringsBuffer = NULL;

   DBBINDING* pBindings = NULL;
   DBOBJECT dbobj;
   ULONG idxBinding;
   IAccessor* pIAccessor = NULL;
   HACCESSOR hAccessor = DB_NULL_HACCESSOR;
   HROW hRows[1] = {DB_NULL_HROW};
   HROW* pRow = &hRows[0];
   BYTE* pBuffer = NULL;

   ULONG lNumRowsRetrieved;
   DBLENGTH dwOffset = 0;

   hr = pIRowset->QueryInterface(IID_IColumnsInfo, (void **)&pIColumnsInfo);
   CHKHR_GOTO(hr, L"Failed to QI Rowset for IColumnsInfo.", _ExitProcessResultSet);

   hr = pIColumnsInfo->GetColumnInfo(&lNumCols, &pDBColumnInfo, &pStringsBuffer);
   CHKHR_GOTO(hr, L"Failed to obtain Column Information.", _ExitProcessResultSet);

   pBindings = new DBBINDING[lNumCols];

   if (!pBindings)
   {
      hr = E_OUTOFMEMORY;
      goto _ExitProcessResultSet;
   }

   memset(pBindings, 0, sizeof(DBBINDING) * lNumCols);

   dbobj.dwFlags = STGM_READ;
   dbobj.iid = IID_ISequentialStream;

   for (idxBinding = 0; idxBinding < lNumCols; idxBinding++) 
   {
      pBindings[idxBinding].iOrdinal = idxBinding + 1;
      pBindings[idxBinding].obStatus = dwOffset;
      pBindings[idxBinding].obLength = dwOffset + sizeof(DBSTATUS);
      pBindings[idxBinding].obValue = dwOffset + sizeof(DBSTATUS) + sizeof(DBLENGTH);

      pBindings[idxBinding].pTypeInfo = NULL;
      pBindings[idxBinding].pBindExt = NULL;
      pBindings[idxBinding].dwPart = DBPART_VALUE | DBPART_LENGTH | DBPART_STATUS;
      pBindings[idxBinding].dwMemOwner = DBMEMOWNER_CLIENTOWNED;
      pBindings[idxBinding].eParamIO = DBPARAMIO_NOTPARAM;
      pBindings[idxBinding].bPrecision = pDBColumnInfo[idxBinding].bPrecision;
      pBindings[idxBinding].bScale = pDBColumnInfo[idxBinding].bScale;

      pBindings[idxBinding].cbMaxLen = 0;
      pBindings[idxBinding].wType = DBTYPE_WSTR;

   // Determine the maximum number of bytes required in our buffer to
   // contain the Unicode string representation of the provider's native
   // data type, including room for the NULL-termination character
   switch( pDBColumnInfo[idxBinding].wType )
   {
      case DBTYPE_NULL:
      case DBTYPE_EMPTY:
      case DBTYPE_I1:
      case DBTYPE_I2:
      case DBTYPE_I4:
      case DBTYPE_UI1:
      case DBTYPE_UI2:
      case DBTYPE_UI4:
      case DBTYPE_R4:
      case DBTYPE_BOOL:
      case DBTYPE_I8:
      case DBTYPE_UI8:
      case DBTYPE_R8:
      case DBTYPE_CY:
      case DBTYPE_ERROR:
      // When the above types are converted to a string, they
      // will all fit into 25 characters, so use that plus space
      // for the NULL-terminator.

      pBindings[idxBinding].cbMaxLen = (25 + 1) * sizeof(WCHAR);
      break;

      case DBTYPE_DECIMAL:
      case DBTYPE_NUMERIC:
      case DBTYPE_DATE:
      case DBTYPE_DBDATE:
      case DBTYPE_DBTIMESTAMP:
      case DBTYPE_GUID:
      // Converted to a string, the above types will all fit into
      // 50 characters, so use that plus space for the terminator.

      pBindings[idxBinding].cbMaxLen = (50 + 1) * sizeof(WCHAR);
      break;

      case DBTYPE_BYTES:
      // In converting DBTYPE_BYTES to a string, each byte
      // becomes two characters (e.g. 0xFF -> "FF"), so we
      // will use double the maximum size of the column plus
      // include space for the NULL-terminator.

      pBindings[idxBinding].cbMaxLen = (pDBColumnInfo[idxBinding].ulColumnSize * 2 + 1) * sizeof(WCHAR);
      break;

      case DBTYPE_STR:
      case DBTYPE_WSTR:
      case DBTYPE_BSTR:
      // Going from a string to our string representation,
      // we can just take the maximum size of the column,
      // a count of characters, and include space for the
      // terminator, which is not included in the column size.

      pBindings[idxBinding].cbMaxLen = (pDBColumnInfo[idxBinding].ulColumnSize + 1) * sizeof(WCHAR);
      break;

      default:
      // For any other type, we will simply use our maximum
      // column buffer size, since the display size of these
      // columns may be variable (e.g. DBTYPE_VARIANT) or
      // unknown (e.g. provider-specific types).
      pBindings[idxBinding].cbMaxLen = MAX_COL_SIZE;
      break;
   }

   // If the provider's native data type for this column is
   // DBTYPE_IUNKNOWN or this is a BLOB column and the user
   // has requested that we bind BLOB columns as ISequentialStream
   // objects, bind this column as an ISequentialStream object if
   // the provider supports our creating another ISequentialStream
   // binding.
   if(pDBColumnInfo[idxBinding].dwFlags & DBCOLUMNFLAGS_ISLONG)
   {
      pBindings[idxBinding].wType = DBTYPE_IUNKNOWN;

      pBindings[idxBinding].cbMaxLen = sizeof(ISequentialStream*);

      pBindings[idxBinding].pObject = (DBOBJECT *)CoTaskMemAlloc(sizeof(DBOBJECT));

      if (!pBindings[idxBinding].pObject)
      {
         hr = E_OUTOFMEMORY;
         goto _ExitProcessResultSet;
      }

      // Direct the provider to create an ISequentialStream
      // object over the data for this column.
      pBindings[idxBinding].pObject->iid = IID_ISequentialStream;

      // We want read access on the ISequentialStream
      // object that the provider will create for us
      pBindings[idxBinding].pObject->dwFlags = STGM_READ;
      }

      // Ensure that the bound maximum length is no more than the
      // maximum column size in bytes that we've defined.
      pBindings[idxBinding].cbMaxLen = min(pBindings[idxBinding].cbMaxLen, MAX_COL_SIZE);

      // Update the offset past the end of this column's data, so
      // that the next column will begin in the correct place in
      // the buffer.
      dwOffset = pBindings[idxBinding].cbMaxLen + pBindings[idxBinding].obValue;

      // Ensure that the data for the next column will be correctly
      // aligned for all platforms, or, if we're done with columns,
      // that if we allocate space for multiple rows that the data
      // for every row is correctly aligned.
      dwOffset = ROUNDUP(dwOffset);
   }

   hr = pIRowset->QueryInterface(IID_IAccessor, (void **) &pIAccessor);
   CHKHR_GOTO(hr, L"Failed to obtain Accessor interface", _ExitProcessResultSet);

   hr = pIAccessor->CreateAccessor(DBACCESSOR_ROWDATA,
      lNumCols,
      pBindings,
      0,
      &hAccessor,
      NULL);

   CHKHR_GOTO(hr, L"Failed to create Accessor", _ExitProcessResultSet);
   for (idxBinding = 0; idxBinding < lNumCols; idxBinding++) 
   {
      cout << pDBColumnInfo[idxBinding].pwszName << endl;
   }

   lNumRowsRetrieved = 0;

   hr = pIRowset->GetNextRows(
      NULL,
      0,
      1,
      &lNumRowsRetrieved,
      &pRow);

   CHKHR_GOTO(hr, L"Failed to fetch a row from the rowset", _ExitProcessResultSet);

   pBuffer = new BYTE[sizeof(DBSTATUS) + sizeof(DBLENGTH) + sizeof(IUnknown*)];

   if (!pBuffer)
   {
      hr = E_OUTOFMEMORY;
      goto _ExitProcessResultSet;
   }

   while(lNumRowsRetrieved && hr != DB_S_ENDOFROWSET) 
   {
      memset(pBuffer, 0, sizeof(DBSTATUS) + sizeof(DBLENGTH) + sizeof(IUnknown*));

      hr = pIRowset->GetData(hRows[0], hAccessor, pBuffer);
      CHKHR_GOTO(hr, L"Failed to obtain row data", _ExitProcessResultSet);

      for (idxBinding = 0; idxBinding < lNumCols; idxBinding++)
      {
         if (pBindings[idxBinding].wType == DBTYPE_IUNKNOWN)
         {
            BYTE pbBuff[3000];
            ULONG cbNeeded = sizeof(pbBuff)/sizeof(BYTE);
            ULONG cbRead;
            ULONG cbReadTotal = 0;
            ISequentialStream* pISequentialStream = NULL;

            IUnknown* pIUnknown = *((IUnknown**)(pBuffer + pBindings[idxBinding].obValue));
            pIUnknown->QueryInterface(IID_ISequentialStream, (void**)&pISequentialStream);

            do
            {
               hr = pISequentialStream->Read(pbBuff, cbNeeded, &cbRead);
               cbReadTotal += cbRead;
            }
            while (SUCCEEDED(hr) && hr != S_FALSE && cbRead == cbNeeded);

               cout << "Total Bytes Read: " << cbReadTotal << endl;

               pISequentialStream->Release();
               pISequentialStream = NULL;
               pIUnknown->Release();
               pIUnknown = NULL;
            }
         }

         pIRowset->ReleaseRows(1, pRow, NULL, NULL, NULL);

         hr = pIRowset->GetNextRows(NULL,
            0,
            1,
            &lNumRowsRetrieved,
            &pRow);

         CHKHR_GOTO(hr, L"Failed to fetch a row from the rowset.", _ExitProcessResultSet);
   }

_ExitProcessResultSet:

   pIRowset->ReleaseRows(1, pRow, NULL, NULL, NULL);
   delete [] pBuffer;

   if (pIAccessor)
   {
      if (hAccessor != DB_NULL_HACCESSOR)
      {
         pIAccessor->ReleaseAccessor(hAccessor, NULL);
      }

      pIAccessor->Release();
      pIAccessor = NULL;
   }

   if (pBindings)
   {
      for (idxBinding = 0; idxBinding < lNumCols; idxBinding++)
      {
         if (pBindings[idxBinding].pObject)
         CoTaskMemFree(pBindings[idxBinding].pObject);
      }
   }

   delete [] pBindings;

   CoTaskMemFree(pDBColumnInfo);
   CoTaskMemFree(pStringsBuffer);

   if (pIColumnsInfo)
   {
      pIColumnsInfo->Release();
      pIColumnsInfo = NULL;
   }

   return hr;
}

如需有關 SQL Server Native Client OLE DB 提供者如何公開大數值資料類型的詳細資訊,請參閱<BLOB 與 OLE 物件>。

SQL Server Native Client ODBC 驅動程式

SQL Server Native Client ODBC 驅動程式會在接受或傳回 ODBC SQL 資料類型的 ODBC API 函數中,將 varchar(max)varbinary(max)nvarchar(max) 類型公開為 SQL_VARCHAR、SQL_VARBINARY 和 SQL_WVARCHAR。

在報告資料行的最大大小時,驅動程式會報告下列其中一項:

  • 定義的最大大小,例如 varchar(2000) 資料行的最大大小為 2000,或者

  • "unlimited" 這個值,如果是 varchar(max) 資料行則等於 0。

標準轉換規則適用於 varchar(max) 資料行,代表任何對 varchar(2000) 資料行有效的轉換也對 varchar(max) 資料行有效。 相同的規則也適用於 nvarchar(max)varbinary(max) 資料行。

下列是 ODBC API 函數的清單,這些函數經過改良,可用於大數值資料類型:

請參閱

其他資源

SQL Server Native Client 功能