Java Code Examples for org.apache.flink.optimizer.dataproperties.InterestingProperties#addLocalProperties()

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	final InterestingProperties iProps = new InterestingProperties();

	{
		final RequestedGlobalProperties partitioningProps = new RequestedGlobalProperties();
		iProps.addGlobalProperties(partitioningProps);
	}

	{
		final Ordering localOrder = getOperator().getLocalOrder();
		final RequestedLocalProperties orderProps = new RequestedLocalProperties();
		if (localOrder != null) {
			orderProps.setOrdering(localOrder);
		}
		iProps.addLocalProperties(orderProps);
	}
	
	this.input.setInterestingProperties(iProps);
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	final InterestingProperties iProps = new InterestingProperties();

	{
		final RequestedGlobalProperties partitioningProps = new RequestedGlobalProperties();
		iProps.addGlobalProperties(partitioningProps);
	}

	{
		final Ordering localOrder = getOperator().getLocalOrder();
		final RequestedLocalProperties orderProps = new RequestedLocalProperties();
		if (localOrder != null) {
			orderProps.setOrdering(localOrder);
		}
		iProps.addLocalProperties(orderProps);
	}
	
	this.input.setInterestingProperties(iProps);
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	final InterestingProperties iProps = new InterestingProperties();

	{
		final RequestedGlobalProperties partitioningProps = new RequestedGlobalProperties();
		iProps.addGlobalProperties(partitioningProps);
	}

	{
		final Ordering localOrder = getOperator().getLocalOrder();
		final RequestedLocalProperties orderProps = new RequestedLocalProperties();
		if (localOrder != null) {
			orderProps.setOrdering(localOrder);
		}
		iProps.addLocalProperties(orderProps);
	}
	
	this.input.setInterestingProperties(iProps);
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) { 
	final InterestingProperties props = getInterestingProperties();
	
	// if no other properties exist, add the pruned trivials back
	if (props.getGlobalProperties().isEmpty()) {
		props.addGlobalProperties(new RequestedGlobalProperties());
	}
	props.addLocalProperties(new RequestedLocalProperties());
	this.input1.setInterestingProperties(props.clone());
	this.input2.setInterestingProperties(props.clone());
	
	this.channelProps = props.getGlobalProperties();
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	// get what we inherit and what is preserved by our user code 
	final InterestingProperties props1 = getInterestingProperties().filterByCodeAnnotations(this, 0);
	final InterestingProperties props2 = getInterestingProperties().filterByCodeAnnotations(this, 1);
	
	// add all properties relevant to this node
	for (OperatorDescriptorDual dpd : getProperties()) {
		for (GlobalPropertiesPair gp : dpd.getPossibleGlobalProperties()) {
			// input 1
			props1.addGlobalProperties(gp.getProperties1());
			
			// input 2
			props2.addGlobalProperties(gp.getProperties2());
		}
		for (LocalPropertiesPair lp : dpd.getPossibleLocalProperties()) {
			// input 1
			props1.addLocalProperties(lp.getProperties1());
			
			// input 2
			props2.addLocalProperties(lp.getProperties2());
		}
	}
	this.input1.setInterestingProperties(props1);
	this.input2.setInterestingProperties(props2);
	
	for (DagConnection conn : getBroadcastConnections()) {
		conn.setInterestingProperties(new InterestingProperties());
	}
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	// get what we inherit and what is preserved by our user code 
	final InterestingProperties props = getInterestingProperties().filterByCodeAnnotations(this, 0);
	
	// add all properties relevant to this node
	for (OperatorDescriptorSingle dps : getPossibleProperties()) {
		for (RequestedGlobalProperties gp : dps.getPossibleGlobalProperties()) {
			
			if (gp.getPartitioning().isPartitionedOnKey()) {
				// make sure that among the same partitioning types, we do not push anything down that has fewer key fields
				
				for (RequestedGlobalProperties contained : props.getGlobalProperties()) {
					if (contained.getPartitioning() == gp.getPartitioning() && gp.getPartitionedFields().isValidSubset(contained.getPartitionedFields())) {
						props.getGlobalProperties().remove(contained);
						break;
					}
				}
			}
			
			props.addGlobalProperties(gp);
		}
		
		for (RequestedLocalProperties lp : dps.getPossibleLocalProperties()) {
			props.addLocalProperties(lp);
		}
	}
	this.inConn.setInterestingProperties(props);
	
	for (DagConnection conn : getBroadcastConnections()) {
		conn.setInterestingProperties(new InterestingProperties());
	}
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) { 
	final InterestingProperties props = getInterestingProperties();
	
	// if no other properties exist, add the pruned trivials back
	if (props.getGlobalProperties().isEmpty()) {
		props.addGlobalProperties(new RequestedGlobalProperties());
	}
	props.addLocalProperties(new RequestedLocalProperties());
	this.input1.setInterestingProperties(props.clone());
	this.input2.setInterestingProperties(props.clone());
	
	this.channelProps = props.getGlobalProperties();
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	// get what we inherit and what is preserved by our user code 
	final InterestingProperties props1 = getInterestingProperties().filterByCodeAnnotations(this, 0);
	final InterestingProperties props2 = getInterestingProperties().filterByCodeAnnotations(this, 1);
	
	// add all properties relevant to this node
	for (OperatorDescriptorDual dpd : getProperties()) {
		for (GlobalPropertiesPair gp : dpd.getPossibleGlobalProperties()) {
			// input 1
			props1.addGlobalProperties(gp.getProperties1());
			
			// input 2
			props2.addGlobalProperties(gp.getProperties2());
		}
		for (LocalPropertiesPair lp : dpd.getPossibleLocalProperties()) {
			// input 1
			props1.addLocalProperties(lp.getProperties1());
			
			// input 2
			props2.addLocalProperties(lp.getProperties2());
		}
	}
	this.input1.setInterestingProperties(props1);
	this.input2.setInterestingProperties(props2);
	
	for (DagConnection conn : getBroadcastConnections()) {
		conn.setInterestingProperties(new InterestingProperties());
	}
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	// get what we inherit and what is preserved by our user code 
	final InterestingProperties props = getInterestingProperties().filterByCodeAnnotations(this, 0);
	
	// add all properties relevant to this node
	for (OperatorDescriptorSingle dps : getPossibleProperties()) {
		for (RequestedGlobalProperties gp : dps.getPossibleGlobalProperties()) {
			
			if (gp.getPartitioning().isPartitionedOnKey()) {
				// make sure that among the same partitioning types, we do not push anything down that has fewer key fields
				
				for (RequestedGlobalProperties contained : props.getGlobalProperties()) {
					if (contained.getPartitioning() == gp.getPartitioning() && gp.getPartitionedFields().isValidSubset(contained.getPartitionedFields())) {
						props.getGlobalProperties().remove(contained);
						break;
					}
				}
			}
			
			props.addGlobalProperties(gp);
		}
		
		for (RequestedLocalProperties lp : dps.getPossibleLocalProperties()) {
			props.addLocalProperties(lp);
		}
	}
	this.inConn.setInterestingProperties(props);
	
	for (DagConnection conn : getBroadcastConnections()) {
		conn.setInterestingProperties(new InterestingProperties());
	}
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) { 
	final InterestingProperties props = getInterestingProperties();
	
	// if no other properties exist, add the pruned trivials back
	if (props.getGlobalProperties().isEmpty()) {
		props.addGlobalProperties(new RequestedGlobalProperties());
	}
	props.addLocalProperties(new RequestedLocalProperties());
	this.input1.setInterestingProperties(props.clone());
	this.input2.setInterestingProperties(props.clone());
	
	this.channelProps = props.getGlobalProperties();
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	// get what we inherit and what is preserved by our user code 
	final InterestingProperties props1 = getInterestingProperties().filterByCodeAnnotations(this, 0);
	final InterestingProperties props2 = getInterestingProperties().filterByCodeAnnotations(this, 1);
	
	// add all properties relevant to this node
	for (OperatorDescriptorDual dpd : getProperties()) {
		for (GlobalPropertiesPair gp : dpd.getPossibleGlobalProperties()) {
			// input 1
			props1.addGlobalProperties(gp.getProperties1());
			
			// input 2
			props2.addGlobalProperties(gp.getProperties2());
		}
		for (LocalPropertiesPair lp : dpd.getPossibleLocalProperties()) {
			// input 1
			props1.addLocalProperties(lp.getProperties1());
			
			// input 2
			props2.addLocalProperties(lp.getProperties2());
		}
	}
	this.input1.setInterestingProperties(props1);
	this.input2.setInterestingProperties(props2);
	
	for (DagConnection conn : getBroadcastConnections()) {
		conn.setInterestingProperties(new InterestingProperties());
	}
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	// get what we inherit and what is preserved by our user code 
	final InterestingProperties props = getInterestingProperties().filterByCodeAnnotations(this, 0);
	
	// add all properties relevant to this node
	for (OperatorDescriptorSingle dps : getPossibleProperties()) {
		for (RequestedGlobalProperties gp : dps.getPossibleGlobalProperties()) {
			
			if (gp.getPartitioning().isPartitionedOnKey()) {
				// make sure that among the same partitioning types, we do not push anything down that has fewer key fields
				
				for (RequestedGlobalProperties contained : props.getGlobalProperties()) {
					if (contained.getPartitioning() == gp.getPartitioning() && gp.getPartitionedFields().isValidSubset(contained.getPartitionedFields())) {
						props.getGlobalProperties().remove(contained);
						break;
					}
				}
			}
			
			props.addGlobalProperties(gp);
		}
		
		for (RequestedLocalProperties lp : dps.getPossibleLocalProperties()) {
			props.addLocalProperties(lp);
		}
	}
	this.inConn.setInterestingProperties(props);
	
	for (DagConnection conn : getBroadcastConnections()) {
		conn.setInterestingProperties(new InterestingProperties());
	}
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	// our own solution (the solution set) is always partitioned and this cannot be adjusted
	// depending on what the successor to the workset iteration requests. for that reason,
	// we ignore incoming interesting properties.
	
	// in addition, we need to make 2 interesting property passes, because the root of the step function 
	// that computes the next workset needs the interesting properties as generated by the
	// workset source of the step function. the second pass concerns only the workset path.
	// as initial interesting properties, we have the trivial ones for the step function,
	// and partitioned on the solution set key for the solution set delta 
	
	RequestedGlobalProperties partitionedProperties = new RequestedGlobalProperties();
	partitionedProperties.setHashPartitioned(this.solutionSetKeyFields);
	InterestingProperties partitionedIP = new InterestingProperties();
	partitionedIP.addGlobalProperties(partitionedProperties);
	partitionedIP.addLocalProperties(new RequestedLocalProperties());
	
	this.nextWorksetRootConnection.setInterestingProperties(new InterestingProperties());
	this.solutionSetDeltaRootConnection.setInterestingProperties(partitionedIP.clone());
	
	InterestingPropertyVisitor ipv = new InterestingPropertyVisitor(estimator);
	this.nextWorkset.accept(ipv);
	this.solutionSetDelta.accept(ipv);
	
	// take the interesting properties of the partial solution and add them to the root interesting properties
	InterestingProperties worksetIntProps = this.worksetNode.getInterestingProperties();
	InterestingProperties intProps = new InterestingProperties();
	intProps.getGlobalProperties().addAll(worksetIntProps.getGlobalProperties());
	intProps.getLocalProperties().addAll(worksetIntProps.getLocalProperties());
	
	// clear all interesting properties to prepare the second traversal
	this.nextWorksetRootConnection.clearInterestingProperties();
	this.nextWorkset.accept(InterestingPropertiesClearer.INSTANCE);
	
	// 2nd pass
	this.nextWorksetRootConnection.setInterestingProperties(intProps);
	this.nextWorkset.accept(ipv);
	
	// now add the interesting properties of the workset to the workset input
	final InterestingProperties inProps = this.worksetNode.getInterestingProperties().clone();
	inProps.addGlobalProperties(new RequestedGlobalProperties());
	inProps.addLocalProperties(new RequestedLocalProperties());
	this.input2.setInterestingProperties(inProps);
	
	// the partial solution must be hash partitioned, so it has only that as interesting properties
	this.input1.setInterestingProperties(partitionedIP);
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	final InterestingProperties intProps = getInterestingProperties().clone();
	
	if (this.terminationCriterion != null) {
		// first propagate through termination Criterion. since it has no successors, it has no
		// interesting properties
		this.terminationCriterionRootConnection.setInterestingProperties(new InterestingProperties());
		this.terminationCriterion.accept(new InterestingPropertyVisitor(estimator));
	}
	
	// we need to make 2 interesting property passes, because the root of the step function needs also
	// the interesting properties as generated by the partial solution
	
	// give our own interesting properties (as generated by the iterations successors) to the step function and
	// make the first pass
	this.rootConnection.setInterestingProperties(intProps);
	this.nextPartialSolution.accept(new InterestingPropertyVisitor(estimator));
	
	// take the interesting properties of the partial solution and add them to the root interesting properties
	InterestingProperties partialSolutionIntProps = this.partialSolution.getInterestingProperties();
	intProps.getGlobalProperties().addAll(partialSolutionIntProps.getGlobalProperties());
	intProps.getLocalProperties().addAll(partialSolutionIntProps.getLocalProperties());
	
	// clear all interesting properties to prepare the second traversal
	// this clears only the path down from the next partial solution. The paths down
	// from the termination criterion (before they meet the paths down from the next partial solution)
	// remain unaffected by this step
	this.rootConnection.clearInterestingProperties();
	this.nextPartialSolution.accept(InterestingPropertiesClearer.INSTANCE);
	
	// 2nd pass
	this.rootConnection.setInterestingProperties(intProps);
	this.nextPartialSolution.accept(new InterestingPropertyVisitor(estimator));
	
	// now add the interesting properties of the partial solution to the input
	final InterestingProperties inProps = this.partialSolution.getInterestingProperties().clone();
	inProps.addGlobalProperties(new RequestedGlobalProperties());
	inProps.addLocalProperties(new RequestedLocalProperties());
	this.inConn.setInterestingProperties(inProps);
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	final InterestingProperties intProps = getInterestingProperties().clone();
	
	if (this.terminationCriterion != null) {
		// first propagate through termination Criterion. since it has no successors, it has no
		// interesting properties
		this.terminationCriterionRootConnection.setInterestingProperties(new InterestingProperties());
		this.terminationCriterion.accept(new InterestingPropertyVisitor(estimator));
	}
	
	// we need to make 2 interesting property passes, because the root of the step function needs also
	// the interesting properties as generated by the partial solution
	
	// give our own interesting properties (as generated by the iterations successors) to the step function and
	// make the first pass
	this.rootConnection.setInterestingProperties(intProps);
	this.nextPartialSolution.accept(new InterestingPropertyVisitor(estimator));
	
	// take the interesting properties of the partial solution and add them to the root interesting properties
	InterestingProperties partialSolutionIntProps = this.partialSolution.getInterestingProperties();
	intProps.getGlobalProperties().addAll(partialSolutionIntProps.getGlobalProperties());
	intProps.getLocalProperties().addAll(partialSolutionIntProps.getLocalProperties());
	
	// clear all interesting properties to prepare the second traversal
	// this clears only the path down from the next partial solution. The paths down
	// from the termination criterion (before they meet the paths down from the next partial solution)
	// remain unaffected by this step
	this.rootConnection.clearInterestingProperties();
	this.nextPartialSolution.accept(InterestingPropertiesClearer.INSTANCE);
	
	// 2nd pass
	this.rootConnection.setInterestingProperties(intProps);
	this.nextPartialSolution.accept(new InterestingPropertyVisitor(estimator));
	
	// now add the interesting properties of the partial solution to the input
	final InterestingProperties inProps = this.partialSolution.getInterestingProperties().clone();
	inProps.addGlobalProperties(new RequestedGlobalProperties());
	inProps.addLocalProperties(new RequestedLocalProperties());
	this.inConn.setInterestingProperties(inProps);
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	// our own solution (the solution set) is always partitioned and this cannot be adjusted
	// depending on what the successor to the workset iteration requests. for that reason,
	// we ignore incoming interesting properties.
	
	// in addition, we need to make 2 interesting property passes, because the root of the step function 
	// that computes the next workset needs the interesting properties as generated by the
	// workset source of the step function. the second pass concerns only the workset path.
	// as initial interesting properties, we have the trivial ones for the step function,
	// and partitioned on the solution set key for the solution set delta 
	
	RequestedGlobalProperties partitionedProperties = new RequestedGlobalProperties();
	partitionedProperties.setHashPartitioned(this.solutionSetKeyFields);
	InterestingProperties partitionedIP = new InterestingProperties();
	partitionedIP.addGlobalProperties(partitionedProperties);
	partitionedIP.addLocalProperties(new RequestedLocalProperties());
	
	this.nextWorksetRootConnection.setInterestingProperties(new InterestingProperties());
	this.solutionSetDeltaRootConnection.setInterestingProperties(partitionedIP.clone());
	
	InterestingPropertyVisitor ipv = new InterestingPropertyVisitor(estimator);
	this.nextWorkset.accept(ipv);
	this.solutionSetDelta.accept(ipv);
	
	// take the interesting properties of the partial solution and add them to the root interesting properties
	InterestingProperties worksetIntProps = this.worksetNode.getInterestingProperties();
	InterestingProperties intProps = new InterestingProperties();
	intProps.getGlobalProperties().addAll(worksetIntProps.getGlobalProperties());
	intProps.getLocalProperties().addAll(worksetIntProps.getLocalProperties());
	
	// clear all interesting properties to prepare the second traversal
	this.nextWorksetRootConnection.clearInterestingProperties();
	this.nextWorkset.accept(InterestingPropertiesClearer.INSTANCE);
	
	// 2nd pass
	this.nextWorksetRootConnection.setInterestingProperties(intProps);
	this.nextWorkset.accept(ipv);
	
	// now add the interesting properties of the workset to the workset input
	final InterestingProperties inProps = this.worksetNode.getInterestingProperties().clone();
	inProps.addGlobalProperties(new RequestedGlobalProperties());
	inProps.addLocalProperties(new RequestedLocalProperties());
	this.input2.setInterestingProperties(inProps);
	
	// the partial solution must be hash partitioned, so it has only that as interesting properties
	this.input1.setInterestingProperties(partitionedIP);
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	// our own solution (the solution set) is always partitioned and this cannot be adjusted
	// depending on what the successor to the workset iteration requests. for that reason,
	// we ignore incoming interesting properties.
	
	// in addition, we need to make 2 interesting property passes, because the root of the step function 
	// that computes the next workset needs the interesting properties as generated by the
	// workset source of the step function. the second pass concerns only the workset path.
	// as initial interesting properties, we have the trivial ones for the step function,
	// and partitioned on the solution set key for the solution set delta 
	
	RequestedGlobalProperties partitionedProperties = new RequestedGlobalProperties();
	partitionedProperties.setHashPartitioned(this.solutionSetKeyFields);
	InterestingProperties partitionedIP = new InterestingProperties();
	partitionedIP.addGlobalProperties(partitionedProperties);
	partitionedIP.addLocalProperties(new RequestedLocalProperties());
	
	this.nextWorksetRootConnection.setInterestingProperties(new InterestingProperties());
	this.solutionSetDeltaRootConnection.setInterestingProperties(partitionedIP.clone());
	
	InterestingPropertyVisitor ipv = new InterestingPropertyVisitor(estimator);
	this.nextWorkset.accept(ipv);
	this.solutionSetDelta.accept(ipv);
	
	// take the interesting properties of the partial solution and add them to the root interesting properties
	InterestingProperties worksetIntProps = this.worksetNode.getInterestingProperties();
	InterestingProperties intProps = new InterestingProperties();
	intProps.getGlobalProperties().addAll(worksetIntProps.getGlobalProperties());
	intProps.getLocalProperties().addAll(worksetIntProps.getLocalProperties());
	
	// clear all interesting properties to prepare the second traversal
	this.nextWorksetRootConnection.clearInterestingProperties();
	this.nextWorkset.accept(InterestingPropertiesClearer.INSTANCE);
	
	// 2nd pass
	this.nextWorksetRootConnection.setInterestingProperties(intProps);
	this.nextWorkset.accept(ipv);
	
	// now add the interesting properties of the workset to the workset input
	final InterestingProperties inProps = this.worksetNode.getInterestingProperties().clone();
	inProps.addGlobalProperties(new RequestedGlobalProperties());
	inProps.addLocalProperties(new RequestedLocalProperties());
	this.input2.setInterestingProperties(inProps);
	
	// the partial solution must be hash partitioned, so it has only that as interesting properties
	this.input1.setInterestingProperties(partitionedIP);
}
 

@Override
public void computeInterestingPropertiesForInputs(CostEstimator estimator) {
	final InterestingProperties intProps = getInterestingProperties().clone();
	
	if (this.terminationCriterion != null) {
		// first propagate through termination Criterion. since it has no successors, it has no
		// interesting properties
		this.terminationCriterionRootConnection.setInterestingProperties(new InterestingProperties());
		this.terminationCriterion.accept(new InterestingPropertyVisitor(estimator));
	}
	
	// we need to make 2 interesting property passes, because the root of the step function needs also
	// the interesting properties as generated by the partial solution
	
	// give our own interesting properties (as generated by the iterations successors) to the step function and
	// make the first pass
	this.rootConnection.setInterestingProperties(intProps);
	this.nextPartialSolution.accept(new InterestingPropertyVisitor(estimator));
	
	// take the interesting properties of the partial solution and add them to the root interesting properties
	InterestingProperties partialSolutionIntProps = this.partialSolution.getInterestingProperties();
	intProps.getGlobalProperties().addAll(partialSolutionIntProps.getGlobalProperties());
	intProps.getLocalProperties().addAll(partialSolutionIntProps.getLocalProperties());
	
	// clear all interesting properties to prepare the second traversal
	// this clears only the path down from the next partial solution. The paths down
	// from the termination criterion (before they meet the paths down from the next partial solution)
	// remain unaffected by this step
	this.rootConnection.clearInterestingProperties();
	this.nextPartialSolution.accept(InterestingPropertiesClearer.INSTANCE);
	
	// 2nd pass
	this.rootConnection.setInterestingProperties(intProps);
	this.nextPartialSolution.accept(new InterestingPropertyVisitor(estimator));
	
	// now add the interesting properties of the partial solution to the input
	final InterestingProperties inProps = this.partialSolution.getInterestingProperties().clone();
	inProps.addGlobalProperties(new RequestedGlobalProperties());
	inProps.addLocalProperties(new RequestedLocalProperties());
	this.inConn.setInterestingProperties(inProps);
}