IRow::GetColumns (または IRow::Open) と ISequentialStream を使用した列のフェッチ
適用対象: 
SQL Server Azure SQL データベース Azure SQL Managed Instance Azure Synapse Analytics Analytics Platform System (PDW)
大きなデータは、ISequentialStream インターフェイスを使用してバインドまたは取得できます。 バインドされた列の場合、状態フラグ DBSTATUS_S_TRUNCATED は、データが切り捨てられたことを示します。
重要
可能な場合は、Windows 認証を使用します。 Windows 認証が使用できない場合は、実行時に資格情報を入力するようユーザーに求めます。 資格情報をファイルに保存するのは避けてください。 資格情報を保持する必要がある場合は、Win32 Crypto API を使用して暗号化してください。
IRow::GetColumns (または IRow::Open) と ISequentialStream を使用して列をフェッチするには
データ ソースへの接続を確立します。
コマンドを実行します (この例では、ICommandExecute::Execute() が IID_IRow を使用して呼び出されます)。
IRow::Open() または IRow::GetColumns() を使用し、列データをフェッチします。
IRow::Open() を使用し、行で ISequentialStream を開くことができます。 列にバイナリ データのストリームが含まれることを示す DBGUID_STREAM を指定します (これによって、IStream または ISequentialStream を使用して、列からデータを読み取ることができます)。
IRow::GetColumns() を使用すると、DBCOLUMNACCESS 構造体の pData 要素が、ストリーム オブジェクトを指すように設定されます。
ISequentialStream::Read() を繰り返し使用し、指定したバイト数をコンシューマー バッファーに読み込みます。
例
この例では、IRow を使用して単一の行をフェッチする方法を示します。 また、行から一度に 1 つの列を取得します。 この例では、IRow::GetColumns() および IRow::Open() の使用方法も示します。 列のデータの読み取りには ISequentialStream::Read を使用しています。
この記事の Transact-SQL コード サンプルは AdventureWorks2022 または AdventureWorksDW2022 サンプル データベースを使用します。このサンプル データベースは、Microsoft SQL Server サンプルとコミュニティ プロジェクトのホーム ページからダウンロードできます。
1 つ目の (Transact-SQL) コード リストは、サンプルで使用するテーブルを作成します。
ole32.lib と oleaut32.lib を使用して 2 つ目の (C++) コード リストをコンパイルし、実行します。 このアプリケーションは、コンピューターの既定の SQL Server インスタンスに接続します。 一部の Windows オペレーティング システムでは、(localhost) または (local) を実際の SQL Server インスタンスの名前に変更する必要があります。 名前付きインスタンスに接続するには、接続文字列を L"(local)" から L"(local)\\name" に変更します。name は名前付きインスタンスです。 SQL Server Express は、既定で名前付きインスタンスとしてインストールされます。 INCLUDE 環境変数に、msoledbsql.h が保存されているディレクトリが含まれていることを確認します。
3 つ目の (Transact-SQL) コード リストは、サンプルで使用したテーブルを削除します。
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