/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4; fill-column: 100 -*- */ /* * This file is part of the LibreOffice project. * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * * This file incorporates work covered by the following license notice: * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed * with this work for additional information regarding copyright * ownership. The ASF licenses this file to you under the Apache * License, Version 2.0 (the "License"); you may not use this file * except in compliance with the License. You may obtain a copy of * the License at http://www.apache.org/licenses/LICENSE-2.0 . */ #include #include #include #include "Connection.hxx" #include "PreparedStatement.hxx" #include "ResultSet.hxx" #include "ResultSetMetaData.hxx" #include "Util.hxx" #include #include #include #include #include #include using namespace connectivity::firebird; using namespace ::comphelper; using namespace ::osl; using namespace com::sun::star; using namespace com::sun::star::uno; using namespace com::sun::star::lang; using namespace com::sun::star::beans; using namespace com::sun::star::sdbc; using namespace com::sun::star::container; using namespace com::sun::star::io; using namespace com::sun::star::util; IMPLEMENT_SERVICE_INFO(OPreparedStatement,"com.sun.star.sdbcx.firebird.PreparedStatement","com.sun.star.sdbc.PreparedStatement"); OPreparedStatement::OPreparedStatement( Connection* _pConnection, const OUString& sql) :OStatementCommonBase(_pConnection) ,m_sSqlStatement(sql) ,m_pOutSqlda(nullptr) ,m_pInSqlda(nullptr) { SAL_INFO("connectivity.firebird", "OPreparedStatement(). " "sql: " << sql); } void OPreparedStatement::ensurePrepared() { MutexGuard aGuard(m_aMutex); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); if (m_aStatementHandle) return; ISC_STATUS aErr = 0; if (!m_pInSqlda) { m_pInSqlda = static_cast(calloc(1, XSQLDA_LENGTH(10))); m_pInSqlda->version = SQLDA_VERSION1; m_pInSqlda->sqln = 10; } prepareAndDescribeStatement(m_sSqlStatement, m_pOutSqlda, m_pInSqlda); aErr = isc_dsql_describe_bind(m_statusVector, &m_aStatementHandle, 1, m_pInSqlda); if (aErr) { SAL_WARN("connectivity.firebird", "isc_dsql_describe_bind failed"); } else if (m_pInSqlda->sqld > m_pInSqlda->sqln) // Not large enough { short nItems = m_pInSqlda->sqld; free(m_pInSqlda); m_pInSqlda = static_cast(calloc(1, XSQLDA_LENGTH(nItems))); m_pInSqlda->version = SQLDA_VERSION1; m_pInSqlda->sqln = nItems; aErr = isc_dsql_describe_bind(m_statusVector, &m_aStatementHandle, 1, m_pInSqlda); SAL_WARN_IF(aErr, "connectivity.firebird", "isc_dsql_describe_bind failed"); } if (!aErr) mallocSQLVAR(m_pInSqlda); else evaluateStatusVector(m_statusVector, m_sSqlStatement, *this); } OPreparedStatement::~OPreparedStatement() { } void SAL_CALL OPreparedStatement::acquire() throw() { OStatementCommonBase::acquire(); } void SAL_CALL OPreparedStatement::release() throw() { OStatementCommonBase::release(); } Any SAL_CALL OPreparedStatement::queryInterface(const Type& rType) { Any aRet = OStatementCommonBase::queryInterface(rType); if(!aRet.hasValue()) aRet = OPreparedStatement_Base::queryInterface(rType); return aRet; } uno::Sequence< Type > SAL_CALL OPreparedStatement::getTypes() { return concatSequences(OPreparedStatement_Base::getTypes(), OStatementCommonBase::getTypes()); } Reference< XResultSetMetaData > SAL_CALL OPreparedStatement::getMetaData() { ::osl::MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); ensurePrepared(); if(!m_xMetaData.is()) m_xMetaData = new OResultSetMetaData(m_pConnection.get() , m_pOutSqlda); return m_xMetaData; } void SAL_CALL OPreparedStatement::close() { MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); OStatementCommonBase::close(); if (m_pInSqlda) { freeSQLVAR(m_pInSqlda); free(m_pInSqlda); m_pInSqlda = nullptr; } if (m_pOutSqlda) { freeSQLVAR(m_pOutSqlda); free(m_pOutSqlda); m_pOutSqlda = nullptr; } } void SAL_CALL OPreparedStatement::disposing() { close(); } void SAL_CALL OPreparedStatement::setString(sal_Int32 nParameterIndex, const OUString& sInput) { SAL_INFO("connectivity.firebird", "setString(" << nParameterIndex << " , " << sInput << ")"); MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); ensurePrepared(); checkParameterIndex(nParameterIndex); setParameterNull(nParameterIndex, false); OString str = OUStringToOString(sInput , RTL_TEXTENCODING_UTF8 ); XSQLVAR* pVar = m_pInSqlda->sqlvar + (nParameterIndex - 1); int dtype = (pVar->sqltype & ~1); // drop flag bit for now if (str.getLength() > pVar->sqllen) str = str.copy(0, pVar->sqllen); switch (dtype) { case SQL_VARYING: { const sal_Int32 max_varchar_len = 0xFFFF; // First 2 bytes indicate string size if (str.getLength() > max_varchar_len) { str = str.copy(0, max_varchar_len); } const auto nLength = str.getLength(); memcpy(pVar->sqldata, &nLength, 2); // Actual data memcpy(pVar->sqldata + 2, str.getStr(), str.getLength()); break; } case SQL_TEXT: memcpy(pVar->sqldata, str.getStr(), str.getLength()); // Fill remainder with spaces memset(pVar->sqldata + str.getLength(), ' ', pVar->sqllen - str.getLength()); break; case SQL_BLOB: // Clob assert( pVar->sqlsubtype == static_cast(BlobSubtype::Clob) ); setClob(nParameterIndex, sInput ); break; case SQL_SHORT: { sal_Int32 int32Value = sInput.toInt32(); if ( (int32Value < std::numeric_limits::min()) || (int32Value > std::numeric_limits::max()) ) { ::dbtools::throwSQLException( "Value out of range for SQL_SHORT type", ::dbtools::StandardSQLState::INVALID_SQL_DATA_TYPE, *this); } setShort(nParameterIndex, int32Value); break; } case SQL_LONG: { sal_Int32 int32Value = sInput.toInt32(); setInt(nParameterIndex, int32Value); break; } case SQL_INT64: { sal_Int64 int64Value = sInput.toInt64(); setLong(nParameterIndex, int64Value); break; } case SQL_FLOAT: { float floatValue = sInput.toFloat(); setFloat(nParameterIndex, floatValue); break; } case SQL_BOOLEAN: { bool boolValue = sInput.toBoolean(); setBoolean(nParameterIndex, boolValue); break; } default: ::dbtools::throwSQLException( "Incorrect type for setString", ::dbtools::StandardSQLState::INVALID_SQL_DATA_TYPE, *this); } } Reference< XConnection > SAL_CALL OPreparedStatement::getConnection() { MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); return Reference(m_pConnection.get()); } sal_Bool SAL_CALL OPreparedStatement::execute() { SAL_INFO("connectivity.firebird", "executeQuery(). " "Got called with sql: " << m_sSqlStatement); MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); ensurePrepared(); ISC_STATUS aErr; if (m_xResultSet.is()) // Checks whether we have already run the statement. { disposeResultSet(); // Closes the cursor from the last run. // This doesn't actually free the statement -- using DSQL_close closes // the cursor and keeps the statement, using DSQL_drop frees the statement // (and associated cursors). aErr = isc_dsql_free_statement(m_statusVector, &m_aStatementHandle, DSQL_close); if (aErr) { // Do not throw error. Trying to close a closed cursor is not a // critical mistake. OUString sErrMsg = StatusVectorToString(m_statusVector, u"isc_dsql_free_statement: close cursor"); SAL_WARN("connectivity.firebird", sErrMsg); } } aErr = isc_dsql_execute(m_statusVector, &m_pConnection->getTransaction(), &m_aStatementHandle, 1, m_pInSqlda); if (aErr) { SAL_WARN("connectivity.firebird", "isc_dsql_execute failed" ); evaluateStatusVector(m_statusVector, u"isc_dsql_execute", *this); } m_xResultSet = new OResultSet(m_pConnection.get(), m_aMutex, uno::Reference< XInterface >(*this), m_aStatementHandle, m_pOutSqlda); if (getStatementChangeCount() > 0) m_pConnection->notifyDatabaseModified(); return m_xResultSet.is(); // TODO: implement handling of multiple ResultSets. } sal_Int32 SAL_CALL OPreparedStatement::executeUpdate() { execute(); return getStatementChangeCount(); } Reference< XResultSet > SAL_CALL OPreparedStatement::executeQuery() { execute(); return m_xResultSet; } namespace { /** * Take out the number part of a fix point decimal without * the information of where is the fractional part from a * string representation of a number. (e.g. 54.654 -> 54654) */ sal_Int64 toNumericWithoutDecimalPlace(const OUString& sSource) { OUString sNumber(sSource); // cut off leading 0 eventually ( eg. 0.567 -> .567) (void)sSource.startsWith("0", &sNumber); sal_Int32 nDotIndex = sNumber.indexOf('.'); if( nDotIndex < 0) { return sNumber.toInt64(); // no dot -> it's an integer } else { // remove dot OUStringBuffer sBuffer(15); if(nDotIndex > 0) { sBuffer.append(sNumber.subView(0, nDotIndex)); } sBuffer.append(sNumber.subView(nDotIndex + 1)); return sBuffer.makeStringAndClear().toInt64(); } } } //----- XParameters ----------------------------------------------------------- void SAL_CALL OPreparedStatement::setNull(sal_Int32 nIndex, sal_Int32 /*nSqlType*/) { MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); ensurePrepared(); checkParameterIndex(nIndex); setParameterNull(nIndex); } void SAL_CALL OPreparedStatement::setBoolean(sal_Int32 nIndex, sal_Bool bValue) { setValue< sal_Bool >(nIndex, bValue, SQL_BOOLEAN); } template void OPreparedStatement::setValue(sal_Int32 nIndex, const T& nValue, ISC_SHORT nType) { MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); ensurePrepared(); checkParameterIndex(nIndex); setParameterNull(nIndex, false); XSQLVAR* pVar = m_pInSqlda->sqlvar + (nIndex - 1); if ((pVar->sqltype & ~1) != nType) { ::dbtools::throwSQLException( "Incorrect type for setValue", ::dbtools::StandardSQLState::INVALID_SQL_DATA_TYPE, *this); } memcpy(pVar->sqldata, &nValue, sizeof(nValue)); } void SAL_CALL OPreparedStatement::setByte(sal_Int32 nIndex, sal_Int8 nValue) { // there's no TINYINT or equivalent on Firebird, // so do the same as setShort setValue< sal_Int16 >(nIndex, nValue, SQL_SHORT); } void SAL_CALL OPreparedStatement::setShort(sal_Int32 nIndex, sal_Int16 nValue) { setValue< sal_Int16 >(nIndex, nValue, SQL_SHORT); } void SAL_CALL OPreparedStatement::setInt(sal_Int32 nIndex, sal_Int32 nValue) { setValue< sal_Int32 >(nIndex, nValue, SQL_LONG); } void SAL_CALL OPreparedStatement::setLong(sal_Int32 nIndex, sal_Int64 nValue) { setValue< sal_Int64 >(nIndex, nValue, SQL_INT64); } void SAL_CALL OPreparedStatement::setFloat(sal_Int32 nIndex, float nValue) { setValue< float >(nIndex, nValue, SQL_FLOAT); } void SAL_CALL OPreparedStatement::setDouble(sal_Int32 nIndex, double nValue) { MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); ensurePrepared(); XSQLVAR* pVar = m_pInSqlda->sqlvar + (nIndex - 1); short dType = (pVar->sqltype & ~1); // drop flag bit for now short dSubType = pVar->sqlsubtype; // Assume it is a sub type of a number. if(dSubType < 0 || dSubType > 2) { ::dbtools::throwSQLException( "Incorrect number sub type", ::dbtools::StandardSQLState::INVALID_SQL_DATA_TYPE, *this); } // firebird stores scale as a negative number ColumnTypeInfo columnType{ dType, dSubType, static_cast(-pVar->sqlscale) }; // Caller might try to set an integer type here. It makes sense to convert // it instead of throwing an error. switch(columnType.getSdbcType()) { case DataType::SMALLINT: setValue< sal_Int16 >(nIndex, static_cast(nValue), dType); break; case DataType::INTEGER: setValue< sal_Int32 >(nIndex, static_cast(nValue), dType); break; case DataType::BIGINT: setValue< sal_Int64 >(nIndex, static_cast(nValue), dType); break; case DataType::NUMERIC: case DataType::DECIMAL: // take decimal places into account, later on they are removed in makeNumericString setObjectWithInfo(nIndex,Any{nValue}, columnType.getSdbcType(), columnType.getScale()); break; default: setValue< double >(nIndex, nValue, SQL_DOUBLE); // TODO: SQL_D_FLOAT? } } void SAL_CALL OPreparedStatement::setDate(sal_Int32 nIndex, const Date& rDate) { struct tm aCTime; aCTime.tm_mday = rDate.Day; aCTime.tm_mon = rDate.Month -1; aCTime.tm_year = rDate.Year -1900; ISC_DATE aISCDate; isc_encode_sql_date(&aCTime, &aISCDate); setValue< ISC_DATE >(nIndex, aISCDate, SQL_TYPE_DATE); } void SAL_CALL OPreparedStatement::setTime( sal_Int32 nIndex, const css::util::Time& rTime) { struct tm aCTime; aCTime.tm_sec = rTime.Seconds; aCTime.tm_min = rTime.Minutes; aCTime.tm_hour = rTime.Hours; ISC_TIME aISCTime; isc_encode_sql_time(&aCTime, &aISCTime); // Here we "know" that ISC_TIME is simply in units of seconds/ISC_TIME_SECONDS_PRECISION with no // other funkiness, so we can simply add the fraction of a second. aISCTime += rTime.NanoSeconds / (1000000000 / ISC_TIME_SECONDS_PRECISION); setValue< ISC_TIME >(nIndex, aISCTime, SQL_TYPE_TIME); } void SAL_CALL OPreparedStatement::setTimestamp(sal_Int32 nIndex, const DateTime& rTimestamp) { struct tm aCTime; aCTime.tm_sec = rTimestamp.Seconds; aCTime.tm_min = rTimestamp.Minutes; aCTime.tm_hour = rTimestamp.Hours; aCTime.tm_mday = rTimestamp.Day; aCTime.tm_mon = rTimestamp.Month - 1; aCTime.tm_year = rTimestamp.Year - 1900; ISC_TIMESTAMP aISCTimestamp; isc_encode_timestamp(&aCTime, &aISCTimestamp); // As in previous function aISCTimestamp.timestamp_time += rTimestamp.NanoSeconds / (1000000000 / ISC_TIME_SECONDS_PRECISION); setValue< ISC_TIMESTAMP >(nIndex, aISCTimestamp, SQL_TIMESTAMP); } // void OPreparedStatement::set void OPreparedStatement::openBlobForWriting(isc_blob_handle& rBlobHandle, ISC_QUAD& rBlobId) { ISC_STATUS aErr; aErr = isc_create_blob2(m_statusVector, &m_pConnection->getDBHandle(), &m_pConnection->getTransaction(), &rBlobHandle, &rBlobId, 0, // Blob parameter buffer length nullptr); // Blob parameter buffer handle if (aErr) { evaluateStatusVector(m_statusVector, OUString("setBlob failed on " + m_sSqlStatement), *this); assert(false); } } void OPreparedStatement::closeBlobAfterWriting(isc_blob_handle& rBlobHandle) { ISC_STATUS aErr; aErr = isc_close_blob(m_statusVector, &rBlobHandle); if (aErr) { evaluateStatusVector(m_statusVector, u"isc_close_blob failed", *this); assert(false); } } void SAL_CALL OPreparedStatement::setClob(sal_Int32 nParameterIndex, const Reference< XClob >& xClob ) { ::osl::MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); #if SAL_TYPES_SIZEOFPOINTER == 8 isc_blob_handle aBlobHandle = 0; #else isc_blob_handle aBlobHandle = nullptr; #endif ISC_QUAD aBlobId; openBlobForWriting(aBlobHandle, aBlobId); // Max segment size is 2^16 == SAL_MAX_UINT16 // SAL_MAX_UINT16 / 4 is surely enough for UTF-8 // TODO apply max segment size to character encoding sal_Int64 nCharWritten = 1; // XClob is indexed from 1 ISC_STATUS aErr = 0; sal_Int64 nLen = xClob->length(); while ( nLen > nCharWritten ) { sal_Int64 nCharRemain = nLen - nCharWritten; constexpr sal_uInt16 MAX_SIZE = SAL_MAX_UINT16 / 4; sal_uInt16 nWriteSize = std::min(nCharRemain, MAX_SIZE); OString sData = OUStringToOString( xClob->getSubString(nCharWritten, nWriteSize), RTL_TEXTENCODING_UTF8); aErr = isc_put_segment( m_statusVector, &aBlobHandle, sData.getLength(), sData.getStr() ); nCharWritten += nWriteSize; if (aErr) break; } // We need to make sure we close the Blob even if there are errors, hence evaluate // errors after closing. closeBlobAfterWriting(aBlobHandle); if (aErr) { evaluateStatusVector(m_statusVector, u"isc_put_segment failed", *this); assert(false); } setValue< ISC_QUAD >(nParameterIndex, aBlobId, SQL_BLOB); } void OPreparedStatement::setClob( sal_Int32 nParameterIndex, const OUString& rStr ) { ::osl::MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); checkParameterIndex(nParameterIndex); #if SAL_TYPES_SIZEOFPOINTER == 8 isc_blob_handle aBlobHandle = 0; #else isc_blob_handle aBlobHandle = nullptr; #endif ISC_QUAD aBlobId; openBlobForWriting(aBlobHandle, aBlobId); OString sData = OUStringToOString( rStr, RTL_TEXTENCODING_UTF8); ISC_STATUS aErr = isc_put_segment( m_statusVector, &aBlobHandle, sData.getLength(), sData.getStr() ); // We need to make sure we close the Blob even if there are errors, hence evaluate // errors after closing. closeBlobAfterWriting(aBlobHandle); if (aErr) { evaluateStatusVector(m_statusVector, u"isc_put_segment failed", *this); assert(false); } setValue< ISC_QUAD >(nParameterIndex, aBlobId, SQL_BLOB); } void SAL_CALL OPreparedStatement::setBlob(sal_Int32 nParameterIndex, const Reference< XBlob >& xBlob) { ::osl::MutexGuard aGuard(m_aMutex); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); checkParameterIndex(nParameterIndex); #if SAL_TYPES_SIZEOFPOINTER == 8 isc_blob_handle aBlobHandle = 0; #else isc_blob_handle aBlobHandle = nullptr; #endif ISC_QUAD aBlobId; openBlobForWriting(aBlobHandle, aBlobId); ISC_STATUS aErr = 0; const sal_Int64 nBlobLen = xBlob->length(); if (nBlobLen > 0) { // Max write size is 0xFFFF == SAL_MAX_UINT16 sal_uInt64 nDataWritten = 0; while (sal::static_int_cast(nBlobLen) > nDataWritten) { sal_uInt64 nDataRemaining = nBlobLen - nDataWritten; sal_uInt16 nWriteSize = std::min(nDataRemaining, sal_uInt64(SAL_MAX_UINT16)); aErr = isc_put_segment(m_statusVector, &aBlobHandle, nWriteSize, reinterpret_cast(xBlob->getBytes(nDataWritten, nWriteSize).getConstArray())); nDataWritten += nWriteSize; if (aErr) break; } } // We need to make sure we close the Blob even if there are errors, hence evaluate // errors after closing. closeBlobAfterWriting(aBlobHandle); if (aErr) { evaluateStatusVector(m_statusVector, u"isc_put_segment failed", *this); assert(false); } setValue< ISC_QUAD >(nParameterIndex, aBlobId, SQL_BLOB); } void SAL_CALL OPreparedStatement::setArray( sal_Int32 nIndex, const Reference< XArray >& ) { ::osl::MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); checkParameterIndex(nIndex); } void SAL_CALL OPreparedStatement::setRef( sal_Int32 nIndex, const Reference< XRef >& ) { ::osl::MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); checkParameterIndex(nIndex); } void SAL_CALL OPreparedStatement::setObjectWithInfo( sal_Int32 parameterIndex, const Any& x, sal_Int32 sqlType, sal_Int32 scale ) { checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); ::osl::MutexGuard aGuard( m_aMutex ); ensurePrepared(); checkParameterIndex(parameterIndex); setParameterNull(parameterIndex, false); XSQLVAR* pVar = m_pInSqlda->sqlvar + (parameterIndex - 1); int dType = (pVar->sqltype & ~1); // drop null flag if(sqlType == DataType::DECIMAL || sqlType == DataType::NUMERIC) { double dbValue =0.0; OUString sValue; if( x >>= dbValue ) { // truncate and round to 'scale' number of decimal places sValue = OUString::number( std::floor((dbValue * pow10Integer(scale)) + .5) / pow10Integer(scale) ); } else { x >>= sValue; } // fill in the number with nulls in fractional part. // We need this because e.g. 0.450 != 0.045 despite // their scale is equal OUStringBuffer sBuffer(15); sBuffer.append(sValue); if(sValue.indexOf('.') != -1) // there is a dot { for(sal_Int32 i=sValue.copy(sValue.indexOf('.')+1).getLength(); i(parameterIndex, static_cast( toNumericWithoutDecimalPlace(sValue) ), dType); break; case SQL_LONG: case SQL_DOUBLE: setValue< sal_Int32 >(parameterIndex, static_cast( toNumericWithoutDecimalPlace(sValue) ), dType); break; case SQL_INT64: setValue< sal_Int64 >(parameterIndex, toNumericWithoutDecimalPlace(sValue), dType); break; default: SAL_WARN("connectivity.firebird", "No Firebird sql type found for numeric or decimal types"); ::dbtools::setObjectWithInfo(this,parameterIndex,x,sqlType,scale); } } else { ::dbtools::setObjectWithInfo(this,parameterIndex,x,sqlType,scale); } } void SAL_CALL OPreparedStatement::setObjectNull( sal_Int32 nIndex, sal_Int32, const OUString& ) { ::osl::MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); checkParameterIndex(nIndex); } void SAL_CALL OPreparedStatement::setObject( sal_Int32 nIndex, const Any& ) { ::osl::MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); checkParameterIndex(nIndex); } void SAL_CALL OPreparedStatement::setBytes(sal_Int32 nParameterIndex, const Sequence< sal_Int8 >& xBytes) { ::osl::MutexGuard aGuard(m_aMutex); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); checkParameterIndex(nParameterIndex); XSQLVAR* pVar = m_pInSqlda->sqlvar + (nParameterIndex - 1); int dType = (pVar->sqltype & ~1); // drop flag bit for now if( dType == SQL_BLOB ) { #if SAL_TYPES_SIZEOFPOINTER == 8 isc_blob_handle aBlobHandle = 0; #else isc_blob_handle aBlobHandle = nullptr; #endif ISC_QUAD aBlobId; openBlobForWriting(aBlobHandle, aBlobId); ISC_STATUS aErr = 0; const sal_Int32 nBytesLen = xBytes.getLength(); if (nBytesLen > 0) { // Max write size is 0xFFFF == SAL_MAX_UINT16 sal_uInt32 nDataWritten = 0; while (sal::static_int_cast(nBytesLen) > nDataWritten) { sal_uInt32 nDataRemaining = nBytesLen - nDataWritten; sal_uInt16 nWriteSize = std::min(nDataRemaining, sal_uInt32(SAL_MAX_UINT16)); aErr = isc_put_segment(m_statusVector, &aBlobHandle, nWriteSize, reinterpret_cast(xBytes.getConstArray()) + nDataWritten); nDataWritten += nWriteSize; if (aErr) break; } } // We need to make sure we close the Blob even if there are errors, hence evaluate // errors after closing. closeBlobAfterWriting(aBlobHandle); if (aErr) { evaluateStatusVector(m_statusVector, u"isc_put_segment failed", *this); assert(false); } setValue< ISC_QUAD >(nParameterIndex, aBlobId, SQL_BLOB); } else if( dType == SQL_VARYING ) { setParameterNull(nParameterIndex, false); const sal_Int32 nMaxSize = 0xFFFF; Sequence xBytesCopy(xBytes); if (xBytesCopy.getLength() > nMaxSize) { xBytesCopy.realloc( nMaxSize ); } const auto nSize = xBytesCopy.getLength(); // 8000 corresponds to value from lcl_addDefaultParameters // in dbaccess/source/filter/hsqldb/createparser.cxx if (nSize > 8000) { free(pVar->sqldata); pVar->sqldata = static_cast(malloc(sizeof(char) * nSize + 2)); } // First 2 bytes indicate string size memcpy(pVar->sqldata, &nSize, 2); // Actual data memcpy(pVar->sqldata + 2, xBytesCopy.getConstArray(), nSize); } else if( dType == SQL_TEXT ) { setParameterNull(nParameterIndex, false); memcpy(pVar->sqldata, xBytes.getConstArray(), xBytes.getLength() ); // Fill remainder with spaces memset(pVar->sqldata + xBytes.getLength(), 0, pVar->sqllen - xBytes.getLength()); } else { ::dbtools::throwSQLException( "Incorrect type for setBytes", ::dbtools::StandardSQLState::INVALID_SQL_DATA_TYPE, *this); } } void SAL_CALL OPreparedStatement::setCharacterStream( sal_Int32 nIndex, const Reference< css::io::XInputStream >&, sal_Int32 ) { ::osl::MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); checkParameterIndex(nIndex); } void SAL_CALL OPreparedStatement::setBinaryStream( sal_Int32 nIndex, const Reference< css::io::XInputStream >&, sal_Int32 ) { ::osl::MutexGuard aGuard( m_aMutex ); checkDisposed(OStatementCommonBase_Base::rBHelper.bDisposed); checkParameterIndex(nIndex); } void SAL_CALL OPreparedStatement::clearParameters( ) { } // ---- Batch methods -- unsupported ----------------------------------------- void SAL_CALL OPreparedStatement::clearBatch() { // Unsupported } void SAL_CALL OPreparedStatement::addBatch() { // Unsupported by firebird } Sequence< sal_Int32 > SAL_CALL OPreparedStatement::executeBatch() { // Unsupported by firebird return Sequence< sal_Int32 >(); } void OPreparedStatement::setFastPropertyValue_NoBroadcast(sal_Int32 nHandle,const Any& rValue) { switch(nHandle) { case PROPERTY_ID_RESULTSETCONCURRENCY: break; case PROPERTY_ID_RESULTSETTYPE: break; case PROPERTY_ID_FETCHDIRECTION: break; case PROPERTY_ID_USEBOOKMARKS: break; default: OStatementCommonBase::setFastPropertyValue_NoBroadcast(nHandle,rValue); } } void OPreparedStatement::checkParameterIndex(sal_Int32 nParameterIndex) { ensurePrepared(); if ((nParameterIndex == 0) || (nParameterIndex > m_pInSqlda->sqld)) { ::dbtools::throwSQLException( "No column " + OUString::number(nParameterIndex), ::dbtools::StandardSQLState::COLUMN_NOT_FOUND, *this); } } void OPreparedStatement::setParameterNull(sal_Int32 nParameterIndex, bool bSetNull) { XSQLVAR* pVar = m_pInSqlda->sqlvar + (nParameterIndex - 1); if (bSetNull) { pVar->sqltype |= 1; *pVar->sqlind = -1; } else *pVar->sqlind = 0; } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */