Abrufen von Spalten mithilfe von IRow::GetColumns (oder IRow::Open) und ISequentialStream
Gilt für: 
SQL Server Azure SQL-Datenbank Azure SQL Managed Instance Azure Synapse Analytics Analytics Platform System (PDW)
Umfangreiche Daten können mit der ISequentialStream-Schnittstelle gebunden oder abgerufen werden. Bei gebundenen Spalten gibt das Statusflag DBSTATUS_S_TRUNCATED an, dass die Daten abgeschnitten werden.
Wichtig
Verwenden Sie nach Möglichkeit die Windows-Authentifizierung. Wenn die Windows-Authentifizierung nicht verfügbar ist, fordern Sie die Benutzer auf, ihre Anmeldeinformationen zur Laufzeit einzugeben. Die Anmeldeinformationen sollten nicht in einer Datei gespeichert werden. Wenn Sie die Anmeldeinformationen permanent speichern müssen, verschlüsseln Sie sie mit der Win32 Crypto-API.
So rufen Sie Spalten mithilfe von IRow::GetColumns (oder IRow::Open) und ISequentialStream ab
Stellen Sie eine Verbindung mit der Datenquelle her.
Führen Sie den Befehl aus (in diesem Beispiel wird ICommandExecute::Execute() mit IID_IRow aufgerufen).
Rufen Sie die Spaltendaten mithilfe von IRow::Open() oder IRow::GetColumns() ab.
IRow::Open() kann zum Öffnen einer ISequentialStream-Schnittstelle in der Zeile verwendet werden. Geben Sie DBGUID_STREAM an, um anzugeben, dass die Spalte einen Strom von Binärdaten enthält (mit IStream oder ISequentialStream können die Daten anschließend aus der Spalte gelesen werden).
Wenn IRow::GetColumns() verwendet wird, wird das pData-Element der DBCOLUMNACCESS-Struktur so festgelegt, dass es auf ein Datenstromobjekt zeigt.
Verwenden Sie ISequentialStream::Read() mehrmals, um die angegebene Anzahl von Bytes in den Consumerpuffer zu lesen.
Beispiel
Dieses Beispiel zeigt, wie Sie mithilfe von IRow eine einzelne Zeile abrufen können. In diesem Beispiel wird jeweils eine Spalte aus der Zeile abgerufen. In diesem Beispiel wird die Verwendung von IRow::Open() sowie IRow::GetColumns() veranschaulicht. Im Beispiel werden die Spaltendaten mithilfe von ISequentialStream::Read gelesen.
Die Transact-SQL-Codebeispiele in diesem Artikel verwenden die AdventureWorks2022- oder AdventureWorksDW2022-Beispieldatenbank, die Sie von der Homepage Microsoft SQL Server Samples and Community Projects herunterladen können.
Das erste Codelisting (Transact-SQL) erstellt eine Tabelle, die im Beispiel verwendet wird.
Kompilieren Sie mit ole32.lib und oleaut32.lib, und führen Sie das zweite Codelisting (C++) aus. Diese Anwendung stellt eine Verbindung mit der SQL Server-Standardinstanz des Computers her. Bei einigen Windows-Betriebssystemen müssen Sie (localhost) oder (local) in den Namen der SQL Server -Instanz ändern. Ändern Sie zum Herstellen einer Verbindung mit einer benannten Instanz die Verbindungszeichenfolge von L"(local)" in L"(local)\\Name", wobei "Name" die benannte Instanz darstellt. Standardmäßig wird SQL Server Express in einer benannten Instanz installiert. Stellen Sie sicher, dass die INCLUDE-Umgebungsvariable das Verzeichnis einschließt, das „msoledbsql.h“ enthält.
Das dritte Codelisting (Transact-SQL) löscht die im Beispiel verwendete Tabelle.
USE AdventureWorks2022;
GO
IF EXISTS (SELECT name FROM sysobjects WHERE name = 'MyTable')
DROP TABLE MyTable
GO
CREATE TABLE MyTable
(
col1 int,
col2 varchar(50),
col3 char(50),
col4 datetime,
col5 float,
col6 money,
col7 sql_variant,
col8 binary(50),
col9 text,
col10 image
)
GO
-- Enter data
INSERT INTO MyTable
values
(
10,
'abcdefghijklmnopqrstuvwxyz',
'ABCDEFGHIJKLMNOPQRSTUVWXYZ',
'11/1/1999 11:52 AM',
3.14,
99.95,
CONVERT(nchar(50), N'AbCdEfGhIjKlMnOpQrStUvWxYz'),
0x123456789,
REPLICATE('AAAAABBBBB', 500),
REPLICATE(0x123456789, 500)
)
GO
// compile with: ole32.lib oleaut32.lib
#define DBINITCONSTANTS
#define INITGUID
#define OLEDBVER 0x0250 // to include correct interfaces
#include <stdio.h>
#include <windows.h>
#include <iostream>
#include <oledb.h>
#include <msoledbsql.h>
using namespace std;
const int kMaxBuff = 50;
int InitializeAndEstablishConnection();
HRESULT GetColumnSize(IRow* pUnkRow, ULONG iCol);
ULONG PrintData(ULONG iCols, ULONG iStart, DBCOLUMNINFO* prgInfo, DBCOLUMNACCESS* prgColumns);
HRESULT GetColumns(IRow* pUnkRow, ULONG iStart, ULONG iEnd);
HRESULT GetSequentialColumn(IRow* pUnkRow, ULONG iCol, BOOL fOpen = TRUE);
IDBInitialize* pIDBInitialize = NULL;
IDBProperties* pIDBProperties = NULL;
IDBCreateSession* pIDBCreateSession = NULL;
IDBCreateCommand* pIDBCreateCommand = NULL;
ICommandText* pICommandText = NULL;
IRow* pIRow = NULL;
DBCOLUMNINFO* pDBColumnInfo = NULL;
IAccessor* pIAccessor = NULL;
DBPROP InitProperties[4];
DBPROPSET rgInitPropSet[1];
ULONG i, j;
HRESULT hresult;
DBROWCOUNT cNumRows = 0;
ULONG lNumCols;
WCHAR* pStringsBuffer;
DBBINDING* pBindings;
ULONG ConsumerBufColOffset = 0;
HACCESSOR hAccessor;
ULONG lNumRowsRetrieved;
HROW hRows[10];
HROW* pRows = &hRows[0];
int main() {
ULONG iidx = 0;
WCHAR* wCmdString = OLESTR("SELECT * FROM MyTable ");
// Call a function to initialize and establish connection.
if (InitializeAndEstablishConnection() == -1) {
cout << "Failed to initialize and establish connection.\n";
// Insert your code for cleanup and error handling
return -1;
}
// Create a session object.
if (FAILED(pIDBInitialize->QueryInterface( IID_IDBCreateSession, (void**) &pIDBCreateSession))) {
cout << "Failed to obtain IDBCreateSession interface.\n";
// Insert your code for cleanup and error handling
return -1;
}
if (FAILED(pIDBCreateSession->CreateSession( NULL,
IID_IDBCreateCommand,
(IUnknown**) &pIDBCreateCommand))) {
cout << "pIDBCreateSession->CreateSession failed.\n";
// Insert your code for cleanup and error handling
return -1;
}
// Access the ICommandText interface.
if (FAILED(pIDBCreateCommand->CreateCommand( NULL, IID_ICommandText, (IUnknown**) &pICommandText))) {
cout << "Failed to access ICommand interface.\n";
// Insert your code for cleanup and error handling
return -1;
}
// Use SetCommandText() to specify the command text.
if (FAILED(pICommandText->SetCommandText(DBGUID_DBSQL, wCmdString))) {
cout << "Failed to set command text.\n";
// Insert your code for cleanup and error handling
return -1;
}
// Execute the command.
if (FAILED(hresult = pICommandText->Execute( NULL, IID_IRow, NULL, &cNumRows, (IUnknown **) &pIRow))) {
cout << "Failed to execute command.\n";
// Insert your code for cleanup and error handling
return -1;
}
DBORDINAL cColumns = 0;
DBCOLUMNINFO* prgInfo = 0;
OLECHAR* pColNames;
// Get column count
HRESULT hr;
IColumnsInfo* pIColumnsInfo;
hr = pIRow->QueryInterface(IID_IColumnsInfo, (void**) &pIColumnsInfo);
if (FAILED(hr))
goto CLEANUP;
hr = pIColumnsInfo->GetColumnInfo(&cColumns, &prgInfo, &pColNames);
if (FAILED(hr))
goto CLEANUP;
// Get columns (one at a time) using ISequentialStream and Open
// 3rd parameter is by default TRUE indicating use of ISequentialStream and Open.
DBCOLUMNINFO* colInfo;
for ( iidx = 1 ; iidx <= cColumns ; iidx++ ) {
colInfo = (DBCOLUMNINFO*)(prgInfo + (iidx - 1));
if (colInfo->dwFlags & DBCOLUMNFLAGS_ISLONG)
hresult = GetSequentialColumn(pIRow, iidx);
else
hresult = GetColumns(pIRow, iidx, iidx);
}
// Release the Row object.
pIRow->Release();
// Execute the command again.
if (FAILED(hresult = pICommandText->Execute(NULL,
IID_IRow,
NULL,
&cNumRows,
(IUnknown **) &pIRow))) {
cout << "Failed to execute command.\n";
// Insert your code for cleanup and error handling
return -1;
}
// Now get columns (one at a time) using ISequentialStream and GetColumns.
// The 3rd parameter is by default TRUE indicating use of ISequentialStream
// and GetColumns
for ( iidx = 1 ; iidx <= cColumns ; iidx++ ) {
colInfo = (DBCOLUMNINFO*)(prgInfo + (iidx - 1));
if (colInfo->dwFlags & DBCOLUMNFLAGS_ISLONG)
hresult = GetSequentialColumn(pIRow, iidx, FALSE);
else
hresult = GetColumns(pIRow, iidx, iidx);
}
CLEANUP:
// Release memory.
pICommandText->Release();
pIDBCreateCommand->Release();
pIDBCreateSession->Release();
if (FAILED(pIDBInitialize->Uninitialize())) {
// Uninitialize not required, but it fails if an interface has not been released, can be used for debugging.
// cout << "Problem uninitializing.\n";
}
pIDBInitialize->Release();
CoTaskMemFree(prgInfo);
CoTaskMemFree(pColNames);
if( pIColumnsInfo )
pIColumnsInfo->Release();
// Release the COM library.
CoUninitialize();
}
HRESULT GetSequentialColumn(IRow* pUnkRow, ULONG iCol, BOOL fOpen) {
HRESULT hr = NOERROR;
ULONG cbRead = 0;
ULONG cbTotal = 0;
DBORDINAL cColumns = 0;
ULONG cReads = 0;
ISequentialStream* pIStream = NULL;
WCHAR* pBuffer[kMaxBuff]; // 50 chars read by ISequentialStream::Read()
DBCOLUMNINFO* prgInfo = 0;
OLECHAR* pColNames = 0;
IColumnsInfo* pIColumnsInfo;
DBID columnid;
DBCOLUMNACCESS column;
wprintf(L"[RETRIEVING COLUMN %d SEQUENTIALLY]\n", iCol);
// Get column information (basically get column id).
hr = pUnkRow->QueryInterface(IID_IColumnsInfo, (void**) &pIColumnsInfo);
if (FAILED(hr))
goto CLEANUP;
hr = pIColumnsInfo->GetColumnInfo(&cColumns, &prgInfo, &pColNames);
if (FAILED(hr))
goto CLEANUP;
// Get Column ID.
columnid = (prgInfo + (iCol - 1))->columnid;
if (fOpen) { // Get columns using ISequentialStream and IRow::Open
wprintf(L"[RETRIEVING COLUMNS USING ");
wprintf(L" ISequentialSteam and Open]\n");
// Open sequential stream.
hr = pUnkRow->Open(NULL,
&columnid,
DBGUID_STREAM,
0,
IID_ISequentialStream,
(LPUNKNOWN *)&pIStream);
if (FAILED(hr)) {
wprintf(L"Unable to get ISequentialStream interface.\n");
goto CLEANUP;
}
}
else { // Get Columns using IRow::GetColumns and ISequentialStream.
wprintf(L"[RETRIEVING COLUMNS USING ");
wprintf(L" GetColumns and ISequentialStream]\n");
IUnknown* pUnkStream = NULL;
ZeroMemory(&column, sizeof(column));
column.columnid = prgInfo[iCol - 1].columnid;
column.wType = DBTYPE_IUNKNOWN;
column.pData = (LPVOID*) &pUnkStream;
hr = pUnkRow->GetColumns(1, &column);
if (FAILED(hr)) {
wprintf(L"Error executing IRow::GetColumns.\n");
goto CLEANUP;
}
hr = pUnkStream->QueryInterface(IID_ISequentialStream, (LPVOID*) &pIStream);
if (FAILED(hr)) {
wprintf(L"Unable to get ISequentialStream interface ");
wprintf(L"via IRow::GetColumns.\n");
goto CLEANUP;
}
pUnkStream->Release();
}
ZeroMemory(pBuffer, kMaxBuff * sizeof(WCHAR));
// Read 50 chars at a time until no more data.
do {
hr = pIStream->Read(pBuffer, kMaxBuff, &cbRead);
if (FAILED(hr)) {
wprintf(L"Error reading data.\n");
goto CLEANUP;
}
cbTotal = cbTotal + cbRead;
// Print the data
wprintf(L"READ #%d: %-*S\n", ++cReads, kMaxBuff, pBuffer);
} while(cbRead > 0);
wprintf(L"[READ %d bytes for column %d.\n", cbTotal, iCol);
CLEANUP:
if (pIColumnsInfo)
pIColumnsInfo->Release();
CoTaskMemFree(prgInfo);
CoTaskMemFree(pColNames);
if (pIStream)
pIStream->Release();
return hr;
}
BOOL InitColumn(DBCOLUMNACCESS* pCol, DBCOLUMNINFO* pInfo) {
// If maximum possible length of a value column is very large (text or image
// column is read) limit that size to 512 bytes (for illustration purposes).
ULONG ulSize;
if (pInfo->wType == DBTYPE_WSTR || pInfo->wType == DBTYPE_STR)
ulSize = (pInfo->ulColumnSize < 0x7fffffff) ? pInfo->ulColumnSize : 512;
else
ulSize = 128; //default buffer to handle conversion to text of non-string data types
// Verify data buffer is large enough.
if (pCol->cbMaxLen < (ulSize + 1)) {
if (pCol->pData) {
delete [] pCol->pData;
pCol->pData = NULL;
}
// Allocate data buffer
void * p = pCol->pData = new WCHAR[ulSize + 1];
if (!(p /*pCol->pData = new WCHAR[ulSize + 1]*/ ))
return FALSE;
// set the max length of caller-initialized memory.
pCol->cbMaxLen = sizeof(WCHAR) * (ulSize + 1);
// In the above 2 steps, pData is pointing to memory (it is not NULL) and
// cbMaxLen has a value (not 0), so next call to IRow->GetData()
// will read the data from the column.
}
// Clear memory buffer
ZeroMemory((void*) pCol->pData, pCol->cbMaxLen);
// Set properties.
//pCol->wType = DBTYPE_WSTR;
pCol->wType = DBTYPE_WSTR;
pCol->columnid = pInfo->columnid;
pCol->cbDataLen = 0;
pCol->dwStatus = 0;
pCol->dwReserved = 0;
pCol->bPrecision = 0;
pCol->bScale = 0;
return TRUE;
}
HRESULT GetColumns(IRow* pUnkRow, ULONG iStart, ULONG iEnd) {
// Start and end are same. Thus, get only one column.
HRESULT hr = E_FAIL;
ULONG iidx; // loop counter
DBORDINAL cColumns; // Count of columns
ULONG cUserCols; // Count of user columns
DBCOLUMNINFO* prgInfo; // Column of info. array
OLECHAR* pColNames; // Array of column names
DBCOLUMNACCESS* prgColumns; // Ptr to column access structures array
DBCOLUMNINFO* pCurrInfo;
DBCOLUMNACCESS* pCurrCol;
IColumnsInfo* pIColumnsInfo = NULL;
// Initialize
cColumns = 0;
prgInfo = NULL;
pColNames = NULL;
prgColumns = NULL;
printf("Retrieving data with GetColumns\n");
// Get column info to build column access array
hr = pUnkRow->QueryInterface(IID_IColumnsInfo, (void**)&pIColumnsInfo);
if (FAILED(hr))
goto CLEANUP;
hr = pIColumnsInfo->GetColumnInfo(&cColumns, &prgInfo, &pColNames);
if (FAILED(hr))
goto CLEANUP;
// Determine no. of columns to retrieve. Since iEnd and iStart is same,
// this is redundent step. cUserCols will always be 1.
cUserCols = iEnd - iStart + 1;
// Walk list of columns and setup a DBCOLUMNACCESS structure
DBCOLUMNACCESS * x = (prgColumns = new DBCOLUMNACCESS[cUserCols]);
if (!(x /*prgColumns = new DBCOLUMNACCESS[cUserCols]*/ )) { // cUserCols is only 1
hr = E_FAIL;
goto CLEANUP;
}
ZeroMemory((void*) prgColumns, sizeof(DBCOLUMNACCESS) * cUserCols);
for ( iidx = 0 ; iidx < cUserCols ; iidx++ ) {
pCurrInfo = prgInfo + iidx + iStart - 1;
pCurrCol = prgColumns + iidx;
// Here the values of pData and cbMaxLen elements of DBCOLUMNACCESS
// elements is set. Thus IRow->GetColumns() will return actual data.
if ( InitColumn(pCurrCol, pCurrInfo) == FALSE )
goto CLEANUP;
}
hr = pUnkRow->GetColumns(cUserCols, prgColumns); // cUserCols = 1
if (FAILED(hr))
printf("Error occurred\n");
// Show data.
PrintData(cUserCols, iStart, prgInfo, prgColumns);
CLEANUP:
if (pIColumnsInfo)
pIColumnsInfo->Release();
if (prgColumns)
delete [] prgColumns;
return hr;
}
// This function returns the actual width of the data in the column (not the
// columnwidth in DBCOLUMNFO structure which is the width of the column)
HRESULT GetColumnSize(IRow* pUnkRow, ULONG iCol) {
HRESULT hr = NOERROR;
DBORDINAL cColumns = 0; // Count the columns
DBCOLUMNINFO* prgInfo; // Column info array
OLECHAR* pColNames;
DBCOLUMNACCESS column;
DBCOLUMNINFO* pCurrInfo;
IColumnsInfo* pIColumnsInfo = NULL;
// Initialize
prgInfo = NULL;
pColNames = NULL;
printf("Checking column size\n");
// Get column info to build column access array
hr = pUnkRow->QueryInterface(IID_IColumnsInfo, (void**) &pIColumnsInfo);
if (FAILED(hr))
goto CLEANUP;
hr = pIColumnsInfo->GetColumnInfo(&cColumns, &prgInfo, &pColNames);
if (FAILED(hr))
goto CLEANUP;
printf("Value of cColumns is %d\n", cColumns);
// Setup a DBCOLUMNACCESS structure: pData is set to NULL and cbMaxLen is set
// to 0. Thus IRow->GetColumns() returns only the actual column length in
// cbDataLen member of DBCOLUMNACCESS structure.In this case you can call
// IRow->GetColumns() again for the same column to retrieve actual data in the second call.
ZeroMemory((void*) &column, sizeof(DBCOLUMNACCESS));
column.pData = NULL;
pCurrInfo = prgInfo + iCol - 1;
// Get column id in DBCOLUMNACCESS structure. It is then used in GetColumn().
column.columnid = pCurrInfo->columnid;
printf("column.columnid value is %d\n", column.columnid);
// We know which column to get. The column.columnid gives the column number.
hr = pUnkRow->GetColumns(1, &column);
if (FAILED(hr))
printf("Errors occurred\n");
// Show data
PrintData(1, iCol, prgInfo, &column);
CLEANUP:
if (pIColumnsInfo)
pIColumnsInfo->Release();
return hr;
}
BOOL GetStatus(DWORD dwStatus, WCHAR* pwszStatus) {
switch (dwStatus) {
case DBSTATUS_S_OK:
wcscpy_s(pwszStatus, 255, L"DBSTATUS_S_OK");
break;
case DBSTATUS_E_CANTCONVERTVALUE:
wcscpy_s(pwszStatus, 255, L"DBSTATUS_E_CANTCONVERTVALUE");
break;
case DBSTATUS_S_ISNULL:
wcscpy_s(pwszStatus, 255, L"DBSTATUS_S_ISNULL");
break;
case DBSTATUS_E_UNAVAILABLE:
wcscpy_s(pwszStatus, 255, L"DBSTATUS_E_UNAVAILABLE");
break;
case DBSTATUS_S_TRUNCATED:
wcscpy_s(pwszStatus, 255, L"DBSTATUS_S_TRUNCATED");
break;
default:
swprintf_s(pwszStatus, sizeof(pwszStatus), L"OTHER STATUS VALUE: %d", dwStatus);
}
return TRUE;
}
ULONG PrintData(ULONG iCols,
ULONG iStart,
DBCOLUMNINFO* prgInfo,
DBCOLUMNACCESS* prgColumns) {
WCHAR wszStatus[255];
DBCOLUMNINFO* pCurrInfo;
DBCOLUMNACCESS* pCurrCol;
ULONG iidx = 0; // Loop counter
printf("%-3s %-20s %-21s %-9s %-9s %-50s\n", "No.", "Name", "Status", "Length", "Max", "Data");
for ( iidx = 0 ; iidx < iCols ; iidx++ ) {
pCurrInfo = prgInfo + iidx + iStart - 1;
pCurrCol = prgColumns + iidx;
GetStatus(pCurrCol->dwStatus, wszStatus);
// was the data successfully retrieved?
wprintf(L"%-3d %-20s %-21s %-9d %-9d %-50s\n", iStart + iidx,
pCurrInfo->pwszName,
wszStatus,
pCurrCol->cbDataLen,
pCurrCol->cbMaxLen,
pCurrCol->dwStatus == DBSTATUS_S_ISNULL ? L"(NULL)" : (WCHAR*) pCurrCol->pData);
}
wprintf(L"\n");
return iidx;
}
int InitializeAndEstablishConnection() {
// Initialize the COM library.
CoInitialize(NULL);
// Obtain access to the MSOLEDBSQL provider.
hresult = CoCreateInstance(CLSID_MSOLEDBSQL,
NULL,
CLSCTX_INPROC_SERVER,
IID_IDBInitialize,
(void **) &pIDBInitialize);
if(FAILED(hresult)) {
printf("Failed to get IDBInitialize interface.\n");
// Insert your code for cleanup and error handling
return -1;
}
// Initialize the property values needed to establish the connection.
for (i = 0 ; i < 4 ; i++ )
VariantInit(&InitProperties[i].vValue);
// Server name.
InitProperties[0].dwPropertyID = DBPROP_INIT_DATASOURCE;
InitProperties[0].vValue.vt = VT_BSTR;
InitProperties[0].vValue.bstrVal = SysAllocString(L"(local)");
InitProperties[0].dwOptions = DBPROPOPTIONS_REQUIRED;
InitProperties[0].colid = DB_NULLID;
// Database.
InitProperties[1].dwPropertyID = DBPROP_INIT_CATALOG;
InitProperties[1].vValue.vt = VT_BSTR;
InitProperties[1].vValue.bstrVal= SysAllocString(L"AdventureWorks");
InitProperties[1].dwOptions = DBPROPOPTIONS_REQUIRED;
InitProperties[1].colid = DB_NULLID;
// connection
InitProperties[2].dwPropertyID = DBPROP_AUTH_INTEGRATED;
InitProperties[2].vValue.vt = VT_BSTR;
InitProperties[2].vValue.bstrVal= SysAllocString(L"SSPI");
InitProperties[2].dwOptions = DBPROPOPTIONS_REQUIRED;
InitProperties[2].colid = DB_NULLID;
// Now that the properties are set, construct the DBPROPSET structure
// (rgInitPropSet). The DBPROPSET structure is used to pass an array
// of DBPROP structures (InitProperties) to the SetProperties method.
rgInitPropSet[0].guidPropertySet = DBPROPSET_DBINIT;
rgInitPropSet[0].cProperties = 4;
rgInitPropSet[0].rgProperties = InitProperties;
// Set initialization properties.
hresult = pIDBInitialize->QueryInterface(IID_IDBProperties, (void **)&pIDBProperties);
if (FAILED(hresult)) {
cout << "Failed to get IDBProperties interface.\n";
// Insert your code for cleanup and error handling
return -1;
}
hresult = pIDBProperties->SetProperties(1, rgInitPropSet);
if (FAILED(hresult)) {
cout << "Failed to set initialization properties.\n";
// Insert your code for cleanup and error handling
return -1;
}
pIDBProperties->Release();
// Now establish the connection to the data source.
if (FAILED(pIDBInitialize->Initialize())) {
cout << "Problem establishing connection to the data source.\n";
// Insert your code for cleanup and error handling
return -1;
}
return 0;
}
USE AdventureWorks2022;
GO
IF EXISTS (SELECT name FROM sysobjects WHERE name = 'MyTable')
DROP TABLE MyTable
GO