Esempio n. 1
0
HugoOperations::~HugoOperations(){
  deallocRows();
  if (pTrans != NULL)
  {
    pTrans->close();
    pTrans = NULL;
  }
}
Esempio n. 2
0
int 
HugoAsynchTransactions::pkReadRecordsAsynch(Ndb* pNdb, 
				      int records,
				      int batch,
				      int trans,
				      int operations) {

  g_info << "|- Reading records asynchronous..." << endl;

  allocRows(trans*operations);
  int result = executeAsynchOperation(pNdb, records, batch, trans, operations, 
				      NO_READ);

  g_info << "|- " << (unsigned int)transactionsCompleted * operations 
	 << " read..."
	 << endl;

  deallocRows();

  return result;
}
int 
HugoTransactions::pkUpdateRecords(Ndb* pNdb, 
				  int records,
				  int batch,
				  int doSleep){
  int updated = 0;
  int                  r = 0;
  int                  retryAttempt = 0;
  int                  check, b;

  allocRows(batch);

  g_info << "|- Updating records (batch=" << batch << ")..." << endl;
  int batch_no = 0;
  while (r < records){
    if(r + batch > records)
      batch = records - r;

    if (m_thr_count != 0 && m_thr_no != batch_no % m_thr_count)
    {
      r += batch;
      batch_no++;
      continue;
    }
    
    if (retryAttempt >= m_retryMax){
      g_info << "ERROR: has retried this operation " << retryAttempt 
	     << " times, failing!" << endl;
      return NDBT_FAILED;
    }
    
    if (doSleep > 0)
      NdbSleep_MilliSleep(doSleep);

    pTrans = pNdb->startTransaction();
    if (pTrans == NULL) {
      const NdbError err = pNdb->getNdbError();
      
      if (err.status == NdbError::TemporaryError){
	ERR(err);
	NdbSleep_MilliSleep(50);
	retryAttempt++;
	continue;
      }
      ERR(err);
      return NDBT_FAILED;
    }

    if(pkReadRecord(pNdb, r, batch, NdbOperation::LM_Exclusive) != NDBT_OK)
    {
      ERR(pTrans->getNdbError());
      closeTransaction(pNdb);
      return NDBT_FAILED;
    }
    
    check = pTrans->execute(NoCommit, AbortOnError);   
    if( check == -1 ) {
      const NdbError err = pTrans->getNdbError();
      
      if (err.status == NdbError::TemporaryError){
	ERR(err);
	closeTransaction(pNdb);
	NdbSleep_MilliSleep(50);
	retryAttempt++;
	continue;
      }
      ERR(err);
      closeTransaction(pNdb);
      return NDBT_FAILED;
    }

    MicroSecondTimer timer_start;
    MicroSecondTimer timer_stop;
    bool timer_active =
      m_stats_latency != 0 &&
      r >= batch &&             // first batch is "warmup"
      r + batch != records;     // last batch is usually partial

    if (timer_active)
      NdbTick_getMicroTimer(&timer_start);

    if(pIndexScanOp)
    {
      int rows_found = 0;
      while((check = pIndexScanOp->nextResult(true)) == 0)
      {
	do {
	  
	  if (calc.verifyRowValues(rows[0]) != 0){
	    closeTransaction(pNdb);
	    return NDBT_FAILED;
	  }
	  
	  int updates = calc.getUpdatesValue(rows[0]) + 1;
	  
	  if(pkUpdateRecord(pNdb, r+rows_found, 1, updates) != NDBT_OK)
	  {
	    ERR(pTrans->getNdbError());
	    closeTransaction(pNdb);
	    return NDBT_FAILED;
	  }
	  rows_found++;
	} while((check = pIndexScanOp->nextResult(false)) == 0);
	
	if(check != 2)
	  break;
	if((check = pTrans->execute(NoCommit, AbortOnError)) != 0)
	  break;
      }
      if(check != 1 || rows_found != batch)
      {
	closeTransaction(pNdb);
	return NDBT_FAILED;
      }
    }
    else
    {
      for(b = 0; b<batch && (b+r)<records; b++)
      {
	if (calc.verifyRowValues(rows[b]) != 0)
	{
	  closeTransaction(pNdb);
	  return NDBT_FAILED;
	}
	
	int updates = calc.getUpdatesValue(rows[b]) + 1;
	
	if(pkUpdateRecord(pNdb, r+b, 1, updates) != NDBT_OK)
	{
	  ERR(pTrans->getNdbError());
	  closeTransaction(pNdb);
	  return NDBT_FAILED;
	}
      }
      check = pTrans->execute(Commit, AbortOnError);   
    }
    if( check == -1 ) {
      const NdbError err = pTrans->getNdbError();

      if (err.status == NdbError::TemporaryError){
	ERR(err);
	closeTransaction(pNdb);
	NdbSleep_MilliSleep(50);
	retryAttempt++;
	continue;
      }
      ERR(err);
      ndbout << "r = " << r << endl;
      closeTransaction(pNdb);
      return NDBT_FAILED;
    }
    else{
      updated += batch;
      m_latest_gci = pTrans->getGCI();
    }
    
    closeTransaction(pNdb);

    if (timer_active) {
      NdbTick_getMicroTimer(&timer_stop);
      NDB_TICKS ticks = NdbTick_getMicrosPassed(timer_start, timer_stop);
      m_stats_latency->addObservation((double)ticks);
    }

    r += batch; // Read next record
    batch_no++;
  }
  
  deallocRows();
  g_info << "|- " << updated << " records updated" << endl;
  return NDBT_OK;
}
int 
HugoTransactions::pkReadRecords(Ndb* pNdb, 
				int records,
				int batch,
				NdbOperation::LockMode lm){
  int                  reads = 0;
  int                  r = 0;
  int                  retryAttempt = 0;
  int                  check;

  if (batch == 0) {
    g_info << "ERROR: Argument batch == 0 in pkReadRecords(). Not allowed." << endl;
    return NDBT_FAILED;
  }

  while (r < records){
    if(r + batch > records)
      batch = records - r;

    if (retryAttempt >= m_retryMax){
      g_info << "ERROR: has retried this operation " << retryAttempt 
	     << " times, failing!" << endl;
      return NDBT_FAILED;
    }
    
    pTrans = pNdb->startTransaction();
    if (pTrans == NULL) {
      const NdbError err = pNdb->getNdbError();
      
      if (err.status == NdbError::TemporaryError){
	ERR(err);
	NdbSleep_MilliSleep(50);
	retryAttempt++;
	continue;
      }
      ERR(err);
      return NDBT_FAILED;
    }

    MicroSecondTimer timer_start;
    MicroSecondTimer timer_stop;
    bool timer_active =
      m_stats_latency != 0 &&
      r >= batch &&             // first batch is "warmup"
      r + batch != records;     // last batch is usually partial

    if (timer_active)
      NdbTick_getMicroTimer(&timer_start);

    if(pkReadRecord(pNdb, r, batch, lm) != NDBT_OK)
    {
      ERR(pTrans->getNdbError());
      closeTransaction(pNdb);
      return NDBT_FAILED;
    }
    
    check = pTrans->execute(Commit, AbortOnError);   
    if( check == -1 ) {
      const NdbError err = pTrans->getNdbError();
      
      if (err.status == NdbError::TemporaryError){
	ERR(err);
	closeTransaction(pNdb);
	NdbSleep_MilliSleep(50);
	retryAttempt++;
	continue;
      }
      switch(err.code){
      case 626: // Tuple did not exist
	g_info << r << ": " << err.code << " " << err.message << endl;
	r++;
	break;

      default:
	ERR(err);
	closeTransaction(pNdb);
	return NDBT_FAILED;
      }
    } else {

      if(pIndexScanOp)
      {
	int rows_found = 0;
	while((check = pIndexScanOp->nextResult()) == 0)
	{
	  rows_found++;
	  if (calc.verifyRowValues(rows[0]) != 0){
	    closeTransaction(pNdb);
	    return NDBT_FAILED;
	  }
	}
	if(check != 1 || rows_found > batch)
	{
	  closeTransaction(pNdb);
	  return NDBT_FAILED;
	}
	else if(rows_found < batch)
	{
	  if(batch == 1){
	    g_info << r << ": not found" << endl; abort(); }
	  else
	    g_info << "Found " << rows_found << " of " 
		   << batch << " rows" << endl;
	}
	r += batch;
	reads += rows_found;
      }
      else 
      {
	for (int b=0; (b<batch) && (r+b<records); b++){ 
	  if (calc.verifyRowValues(rows[b]) != 0){
	    closeTransaction(pNdb);
	    return NDBT_FAILED;
	  }
	  reads++;
	  r++;
	}
      }
    }
    
    closeTransaction(pNdb);

    if (timer_active) {
      NdbTick_getMicroTimer(&timer_stop);
      NDB_TICKS ticks = NdbTick_getMicrosPassed(timer_start, timer_stop);
      m_stats_latency->addObservation((double)ticks);
    }
  }
  deallocRows();
  g_info << reads << " records read" << endl;
  return NDBT_OK;
}
HugoTransactions::~HugoTransactions(){
  deallocRows();
}
int 
HugoTransactions::indexReadRecords(Ndb* pNdb, 
				   const char * idxName,
				   int records,
				   int batch){
  int                  reads = 0;
  int                  r = 0;
  int                  retryAttempt = 0;
  int                  check, a;
  NdbOperation *pOp;
  NdbIndexScanOperation *sOp;

  const NdbDictionary::Index* pIndex
    = pNdb->getDictionary()->getIndex(idxName, tab.getName());
  
  const bool ordered = (pIndex->getType()==NdbDictionary::Index::OrderedIndex);

  if (batch == 0) {
    g_info << "ERROR: Argument batch == 0 in indexReadRecords(). "
	   << "Not allowed." << endl;
    return NDBT_FAILED;
  }
  
  if (ordered) {
    batch = 1;
  }

  allocRows(batch);
  
  while (r < records){
    if (retryAttempt >= m_retryMax){
      g_info << "ERROR: has retried this operation " << retryAttempt 
	     << " times, failing!" << endl;
      return NDBT_FAILED;
    }

    pTrans = pNdb->startTransaction();
    if (pTrans == NULL) {
      const NdbError err = pNdb->getNdbError();
      
      if (err.status == NdbError::TemporaryError){
	ERR(err);
	NdbSleep_MilliSleep(50);
	retryAttempt++;
	continue;
      }
      ERR(err);
      return NDBT_FAILED;
    }
    
    for(int b=0; (b<batch) && (r+b < records); b++){
      if(!ordered){
	pOp = pTrans->getNdbIndexOperation(idxName, tab.getName());	
	if (pOp == NULL) {
	  ERR(pTrans->getNdbError());
	  closeTransaction(pNdb);
	  return NDBT_FAILED;
	}
	check = pOp->readTuple();
      } else {
	pOp = sOp = pTrans->getNdbIndexScanOperation(idxName, tab.getName());
	if (sOp == NULL) {
	  ERR(pTrans->getNdbError());
	  closeTransaction(pNdb);
	  return NDBT_FAILED;
	}
	check = sOp->readTuples();
      }
      
      if( check == -1 ) {
	ERR(pTrans->getNdbError());
	closeTransaction(pNdb);
	return NDBT_FAILED;
      }
      
      // Define primary keys
      if (equalForRow(pOp, r+b) != 0)
      {
        closeTransaction(pNdb);
        return NDBT_FAILED;
      }
      
      // Define attributes to read  
      for(a = 0; a<tab.getNoOfColumns(); a++){
	if((rows[b]->attributeStore(a) = 
	    pOp->getValue(tab.getColumn(a)->getName())) == 0) {
	  ERR(pTrans->getNdbError());
	  closeTransaction(pNdb);
	  return NDBT_FAILED;
	}
      }
    }

    check = pTrans->execute(Commit, AbortOnError);   
    check = (check == -1 ? -1 : !ordered ? check : sOp->nextResult(true));
    if( check == -1 ) {
      const NdbError err = pTrans->getNdbError();
      
      if (err.status == NdbError::TemporaryError){
	ERR(err);
	closeTransaction(pNdb);
	NdbSleep_MilliSleep(50);
	retryAttempt++;
	continue;
      }
      switch(err.code){
      case 626: // Tuple did not exist
	  g_info << r << ": " << err.code << " " << err.message << endl;
	  r++;
	  break;
	  
      default:
	ERR(err);
	closeTransaction(pNdb);
	return NDBT_FAILED;
      }
    } else{
      for (int b=0; (b<batch) && (r+b<records); b++){ 
	if (calc.verifyRowValues(rows[b]) != 0){
	  closeTransaction(pNdb);
	  return NDBT_FAILED;
	}
	reads++;
	r++;
      }
      if(ordered && sOp->nextResult(true) == 0){
	ndbout << "Error when comparing records "
	       << " - index op next_result to many" << endl;
	closeTransaction(pNdb);
	return NDBT_FAILED;
      }
    }
    closeTransaction(pNdb);
  }
  deallocRows();
  g_info << reads << " records read" << endl;
  return NDBT_OK;
}
int 
HugoTransactions::lockRecords(Ndb* pNdb, 
			      int records,
			      int percentToLock,
			      int lockTime){
  // Place a lock on percentToLock% of the records in the Db
  // Keep the locks for lockTime ms, commit operation
  // and lock som other records
  int                  r = 0;
  int                  retryAttempt = 0;
  int                  check;
  NdbOperation::LockMode lm = NdbOperation::LM_Exclusive;

  // Calculate how many records to lock in each batch
  if (percentToLock <= 0)
    percentToLock = 1;
  double percentVal = (double)percentToLock / 100;
  int lockBatch = (int)(records * percentVal);
  if (lockBatch <= 0)
    lockBatch = 1;

  allocRows(lockBatch);
  
  while (r < records){
    if(r + lockBatch > records)
      lockBatch = records - r;
    
    g_info << "|- Locking " << lockBatch << " records..." << endl;

    if (retryAttempt >= m_retryMax){
      g_info << "ERROR: has retried this operation " << retryAttempt 
	     << " times, failing!" << endl;
      return NDBT_FAILED;
    }

    pTrans = pNdb->startTransaction();
    if (pTrans == NULL) {
      const NdbError err = pNdb->getNdbError();

      if (err.status == NdbError::TemporaryError){
	ERR(err);
	NdbSleep_MilliSleep(50);
	retryAttempt++;
	continue;
      }
      ERR(err);
      return NDBT_FAILED;
    }

    if(pkReadRecord(pNdb, r, lockBatch, lm) != NDBT_OK)
    {
      ERR(pTrans->getNdbError());
      closeTransaction(pNdb);
      return NDBT_FAILED;
    }
    
    // NoCommit lockTime times with 100 millis interval
    int sleepInterval = 50;
    int lockCount = lockTime / sleepInterval;
    int commitCount = 0;
    do {
      check = pTrans->execute(NoCommit, AbortOnError);   
      if( check == -1) {
	const NdbError err = pTrans->getNdbError();
	
	if (err.status == NdbError::TemporaryError){
	  ERR(err);
	  closeTransaction(pNdb);
	  NdbSleep_MilliSleep(50);
	  retryAttempt++;
	  continue;
	}
	ERR(err);
	closeTransaction(pNdb);
	return NDBT_FAILED;
      }
      for (int b=0; (b<lockBatch) && (r+b<records); b++){ 
	if (calc.verifyRowValues(rows[b]) != 0){
	  closeTransaction(pNdb);
	  return NDBT_FAILED;
	}
      }
      commitCount++;
      NdbSleep_MilliSleep(sleepInterval);
    } while (commitCount < lockCount);
    
    // Really commit the trans, puuh!
    check = pTrans->execute(Commit, AbortOnError);   
    if( check == -1) {
      const NdbError err = pTrans->getNdbError();
      
      if (err.status == NdbError::TemporaryError){
	ERR(err);
	closeTransaction(pNdb);
	NdbSleep_MilliSleep(50);
	retryAttempt++;
	continue;
      }
      ERR(err);
      closeTransaction(pNdb);
      return NDBT_FAILED;
    }
    else{
      for (int b=0; (b<lockBatch) && (r<records); b++){ 
	if (calc.verifyRowValues(rows[b]) != 0){
	  closeTransaction(pNdb);
	  return NDBT_FAILED;
	}
	r++; // Read next record
      }
    }
    
    closeTransaction(pNdb);
    
  }
  deallocRows();
  g_info << "|- Record locking completed" << endl;
  return NDBT_OK;
}
Esempio n. 8
0
int 
HugoAsynchTransactions::pkUpdateRecordsAsynch(Ndb* pNdb, 
					int records,
					int batch,
					int trans,
					int operations) {

  g_info << "|- Updating records asynchronous..." << endl;

  int             check = 0;
  int             cTrans = 0;
  int             cReadRecords = 0;
  int             cReadIndex = 0;
  int             cRecords = 0;
  int             cIndex = 0;

  transactionsCompleted = 0;

  allocRows(trans*operations);
  allocTransactions(trans);
  int a, t, r;

  for (int i = 0; i < batch; i++) { // For each batch
    while (cRecords < records*batch) {
      cTrans = 0;
      cReadIndex = 0;
      for (t = 0; t < trans; t++) { // For each transaction
	transactions[t] = pNdb->startTransaction();
	if (transactions[t] == NULL) {
	  ERR(pNdb->getNdbError());
	  return NDBT_FAILED;
	}	
	for (int k = 0; k < operations; k++) { // For each operation
	  NdbOperation* pOp = transactions[t]->getNdbOperation(tab.getName());
	  if (pOp == NULL) { 
	    ERR(transactions[t]->getNdbError());
	    pNdb->closeTransaction(transactions[t]);
	    return NDBT_FAILED;
	  }
	  
	  // Read
	  // Define primary keys
	  check = pOp->readTupleExclusive();
	  for (a = 0; a < tab.getNoOfColumns(); a++) {
	    if (tab.getColumn(a)->getPrimaryKey() == true) {
	      if (equalForAttr(pOp, a, cReadRecords) != 0){
		ERR(transactions[t]->getNdbError());
		pNdb->closeTransaction(transactions[t]);
		return NDBT_FAILED;
	      }
	    }
	  }	    
	  // Define attributes to read  
	  for (a = 0; a < tab.getNoOfColumns(); a++) {
	    if ((rows[cReadIndex]->attributeStore(a) = 
		 pOp->getValue(tab.getColumn(a)->getName())) == 0) {
	      ERR(transactions[t]->getNdbError());
	      pNdb->closeTransaction(transactions[t]);
	      return NDBT_FAILED;
	    }
	  }	    	  
	  cReadIndex++;
	  cReadRecords++;
	  
	} // For each operation
	
	// Let's prepare...
	transactions[t]->executeAsynchPrepare(NoCommit, &asynchCallback, 
					this);
	cTrans++;

	if (cReadRecords >= records) {
	  // No more transactions needed
	  break;
	}      
      } // For each transaction

      // Wait for all outstanding transactions
      pNdb->sendPollNdb(3000, 0, 0);

      // Verify the data!
      for (r = 0; r < trans*operations; r++) {
	if (calc.verifyRowValues(rows[r]) != 0) {
	  g_info << "|- Verify failed..." << endl;
	  // Close all transactions
	  for (int t = 0; t < cTrans; t++) {
	    pNdb->closeTransaction(transactions[t]);
	  }
	  return NDBT_FAILED;
	}
      }	

      // Update
      cTrans = 0;
      cIndex = 0;
      for (t = 0; t < trans; t++) { // For each transaction
	for (int k = 0; k < operations; k++) { // For each operation
	  NdbOperation* pOp = transactions[t]->getNdbOperation(tab.getName());
	  if (pOp == NULL) { 
	    ERR(transactions[t]->getNdbError());
	    pNdb->closeTransaction(transactions[t]);
	    return NDBT_FAILED;
	  }
	  
	  int updates = calc.getUpdatesValue(rows[cIndex]) + 1;

	  check = pOp->updateTuple();
	  if (check == -1) {
	    ERR(transactions[t]->getNdbError());
	    pNdb->closeTransaction(transactions[t]);
	      return NDBT_FAILED;
	  }

	  // Set search condition for the record
	  for (a = 0; a < tab.getNoOfColumns(); a++) {
	    if (tab.getColumn(a)->getPrimaryKey() == true) {
	      if (equalForAttr(pOp, a, cRecords) != 0) {
		ERR(transactions[t]->getNdbError());
		pNdb->closeTransaction(transactions[t]);
		return NDBT_FAILED;
	      }
	    }
	  }

	  // Update the record
	  for (a = 0; a < tab.getNoOfColumns(); a++) {
	    if (tab.getColumn(a)->getPrimaryKey() == false) {
	      if (setValueForAttr(pOp, a, cRecords, updates) != 0) {
		ERR(transactions[t]->getNdbError());
		pNdb->closeTransaction(transactions[t]);
		return NDBT_FAILED;
	      }
	    }
	  }	  
	  cIndex++;
	  cRecords++;
	  
	} // For each operation
	
	// Let's prepare...
	transactions[t]->executeAsynchPrepare(Commit, &asynchCallback, 
					this);
	cTrans++;

	if (cRecords >= records) {
	  // No more transactions needed
	  break;
	}      
      } // For each transaction

      // Wait for all outstanding transactions
      pNdb->sendPollNdb(3000, 0, 0);

      // Close all transactions
      for (t = 0; t < cTrans; t++) {
	pNdb->closeTransaction(transactions[t]);
      }

    } // while (cRecords < records*batch)

  } // For each batch

  deallocTransactions();
  deallocRows();
  
  g_info << "|- " << ((unsigned int)transactionsCompleted * operations)/2 
	 << " updated..." << endl;
  return NDBT_OK;
}