/*
* 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
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package com.hp.hpl.jena.sparql.engine.main;
import java.util.ArrayList ;
import java.util.Iterator ;
import java.util.List ;
import org.openjena.atlas.iterator.Iter ;
import org.openjena.atlas.logging.Log ;
import com.hp.hpl.jena.graph.Node ;
import com.hp.hpl.jena.query.QueryExecException ;
import com.hp.hpl.jena.sparql.ARQNotImplemented ;
import com.hp.hpl.jena.sparql.algebra.Op ;
import com.hp.hpl.jena.sparql.algebra.op.* ;
import com.hp.hpl.jena.sparql.core.BasicPattern ;
import com.hp.hpl.jena.sparql.core.Quad ;
import com.hp.hpl.jena.sparql.engine.ExecutionContext ;
import com.hp.hpl.jena.sparql.engine.QueryIterator ;
import com.hp.hpl.jena.sparql.engine.binding.Binding ;
import com.hp.hpl.jena.sparql.engine.iterator.* ;
import com.hp.hpl.jena.sparql.engine.main.iterator.QueryIterGraph ;
import com.hp.hpl.jena.sparql.engine.main.iterator.QueryIterJoin ;
import com.hp.hpl.jena.sparql.engine.main.iterator.QueryIterLeftJoin ;
import com.hp.hpl.jena.sparql.engine.main.iterator.QueryIterOptionalIndex ;
import com.hp.hpl.jena.sparql.engine.main.iterator.QueryIterService ;
import com.hp.hpl.jena.sparql.engine.main.iterator.QueryIterUnion ;
import com.hp.hpl.jena.sparql.expr.Expr ;
import com.hp.hpl.jena.sparql.expr.ExprList ;
import com.hp.hpl.jena.sparql.procedure.ProcEval ;
import com.hp.hpl.jena.sparql.procedure.Procedure ;
/**
* Turn an Op expression into an execution of QueryIterators.
*
* Does not consider optimizing the algebra expression (that should happen
* elsewhere). BGPs are still subject to StageBuilding during iterator
* execution. During execution, when a substitution into an algebra expression
* happens (in other words, a streaming operation, index-join-like), there is a
* call into the executor each time so it does not just happen once before a
* query starts. */
public class OpExecutor
{
// Set this to a different factory implementation to have a different OpExecutor.
protected static final OpExecutorFactory stdFactory = new OpExecutorFactory(){
@Override
public OpExecutor create(ExecutionContext execCxt)
{
return new OpExecutor(execCxt) ;
}} ;
// public static Factory factory = stdFactory ;
private static OpExecutor createOpExecutor(ExecutionContext execCxt)
{
OpExecutorFactory factory = execCxt.getExecutor() ;
if ( factory == null )
factory = stdFactory ;
if ( factory == null )
return new OpExecutor(execCxt) ;
return factory.create(execCxt) ;
}
// -------
static QueryIterator execute(Op op, ExecutionContext execCxt)
{
return execute(op, createRootQueryIterator(execCxt), execCxt) ;
}
// Public interface is via QC.execute.
static QueryIterator execute(Op op, QueryIterator qIter, ExecutionContext execCxt)
{
OpExecutor exec = createOpExecutor(execCxt) ;
QueryIterator q = exec.executeOp(op, qIter) ;
return q ;
}
// -------- The object starts here --------
protected ExecutionContext execCxt ;
protected ExecutionDispatch dispatcher = null ;
protected static final int TOP_LEVEL = 0 ;
protected int level = TOP_LEVEL-1 ;
protected OpExecutor(ExecutionContext execCxt)
{
this.execCxt = execCxt ;
dispatcher = new ExecutionDispatch(this) ;
}
// public QueryIterator executeOp(Op op)
// {
// return executeOp(op, root()) ;
// }
// ---- The recursive step.
public QueryIterator executeOp(Op op, QueryIterator input)
{
level++ ;
QueryIterator qIter = dispatcher.exec(op, input) ;
// Intentionally not try/finally so exceptions leave some evidence around.
level-- ;
return qIter ;
}
// ---- All the cases
protected QueryIterator execute(OpBGP opBGP, QueryIterator input)
{
BasicPattern pattern = opBGP.getPattern() ;
return StageBuilder.execute(pattern, input, execCxt) ;
}
protected QueryIterator execute(OpTriple opTriple, QueryIterator input)
{
return execute(opTriple.asBGP(), input) ;
}
protected QueryIterator execute(OpQuad opQuad, QueryIterator input)
{
return execute(opQuad.asQuadPattern(), input) ;
}
protected QueryIterator execute(OpQuadPattern quadPattern, QueryIterator input)
{
// Convert to BGP forms to execute in this graph-centric engine.
if ( quadPattern.isDefaultGraph() && execCxt.getActiveGraph() == execCxt.getDataset().getDefaultGraph() )
{
// Note we tested that the containing graph was the dataset's default graph.
// Easy case.
OpBGP opBGP = new OpBGP(quadPattern.getBasicPattern()) ;
return execute(opBGP, input) ;
}
if ( Quad.isUnionGraph(quadPattern.getGraphNode()) )
Log.warn(this, "Not implemented yet: quad/union default graph in general OpExecutor") ;
// Not default graph - (graph .... )
OpBGP opBGP = new OpBGP(quadPattern.getBasicPattern()) ;
OpGraph op = new OpGraph(quadPattern.getGraphNode(), opBGP) ;
return execute(op, input) ;
}
protected QueryIterator execute(OpPath opPath, QueryIterator input)
{
return new QueryIterPath(opPath.getTriplePath(), input, execCxt) ;
}
protected QueryIterator execute(OpProcedure opProc, QueryIterator input)
{
Procedure procedure = ProcEval.build(opProc, execCxt) ;
QueryIterator qIter = executeOp(opProc.getSubOp(), input) ;
// Delay until query starts executing.
return new QueryIterProcedure(qIter, procedure, execCxt) ;
}
protected QueryIterator execute(OpPropFunc opPropFunc, QueryIterator input)
{
Procedure procedure = ProcEval.build(opPropFunc.getProperty(), opPropFunc.getSubjectArgs(),opPropFunc.getObjectArgs(), execCxt) ;
QueryIterator qIter = executeOp(opPropFunc.getSubOp(), input) ;
return new QueryIterProcedure(qIter, procedure, execCxt) ;
}
protected QueryIterator execute(OpJoin opJoin, QueryIterator input)
{
// Need to clone input into left and right.
// Do by evaling for each input case, the left and right and concat'ing the results.
if ( false )
{
// If needed, applies to OpDiff and OpLeftJoin as well.
List<Binding> a = all(input) ;
QueryIterator qIter1 = new QueryIterPlainWrapper(a.iterator(), execCxt) ;
QueryIterator qIter2 = new QueryIterPlainWrapper(a.iterator(), execCxt) ;
QueryIterator left = executeOp(opJoin.getLeft(), qIter1) ;
QueryIterator right = executeOp(opJoin.getRight(), qIter2) ;
QueryIterator qIter = new QueryIterJoin(left, right, execCxt) ;
return qIter ;
}
QueryIterator left = executeOp(opJoin.getLeft(), input) ;
QueryIterator right = executeOp(opJoin.getRight(), root()) ;
QueryIterator qIter = new QueryIterJoin(left, right, execCxt) ;
return qIter ;
}
// Pass iterator from one step directly into the next.
protected QueryIterator execute(OpSequence opSequence, QueryIterator input)
{
QueryIterator qIter = input ;
for ( Iterator<Op> iter = opSequence.iterator() ; iter.hasNext() ; )
{
Op sub = iter.next() ;
qIter = executeOp(sub, qIter) ;
}
return qIter ;
}
// Pass iterator from one step directly into the next.
protected QueryIterator execute(OpDisjunction opDisjunction, QueryIterator input)
{
QueryIterator cIter = new QueryIterUnion(input, opDisjunction.getElements(), execCxt) ;
return cIter ;
}
protected QueryIterator execute(OpLeftJoin opLeftJoin, QueryIterator input)
{
QueryIterator left = executeOp(opLeftJoin.getLeft(), input) ;
QueryIterator right = executeOp(opLeftJoin.getRight(), root()) ;
QueryIterator qIter = new QueryIterLeftJoin(left, right, opLeftJoin.getExprs(), execCxt) ;
return qIter ;
}
protected QueryIterator execute(OpConditional opCondition, QueryIterator input)
{
QueryIterator left = executeOp(opCondition.getLeft(), input) ;
QueryIterator qIter = new QueryIterOptionalIndex(left, opCondition.getRight(), execCxt) ;
return qIter ;
}
protected QueryIterator execute(OpDiff opDiff, QueryIterator input)
{
QueryIterator left = executeOp(opDiff.getLeft(), input) ;
QueryIterator right = executeOp(opDiff.getRight(), root()) ;
return new QueryIterDiff(left, right, execCxt) ;
}
protected QueryIterator execute(OpMinus opMinus, QueryIterator input)
{
QueryIterator left = executeOp(opMinus.getLeft(), input) ;
QueryIterator right = executeOp(opMinus.getRight(), root()) ;
return new QueryIterMinus(left, right, execCxt) ;
}
protected QueryIterator execute(OpUnion opUnion, QueryIterator input)
{
List<Op> x = flattenUnion(opUnion) ;
QueryIterator cIter = new QueryIterUnion(input, x, execCxt) ;
return cIter ;
}
// Based on code from Olaf Hartig.
protected List<Op> flattenUnion(OpUnion opUnion)
{
List<Op> x = new ArrayList<Op>() ;
flattenUnion(x, opUnion) ;
return x ;
}
protected void flattenUnion(List<Op> acc, OpUnion opUnion)
{
if (opUnion.getLeft() instanceof OpUnion)
flattenUnion(acc, (OpUnion)opUnion.getLeft()) ;
else
acc.add( opUnion.getLeft() ) ;
if (opUnion.getRight() instanceof OpUnion)
flattenUnion(acc, (OpUnion)opUnion.getRight()) ;
else
acc.add( opUnion.getRight() ) ;
}
protected QueryIterator execute(OpFilter opFilter, QueryIterator input)
{
ExprList exprs = opFilter.getExprs() ;
Op base = opFilter.getSubOp() ;
QueryIterator qIter = executeOp(base, input) ;
for ( Expr expr : exprs )
qIter = new QueryIterFilterExpr(qIter, expr, execCxt) ;
return qIter ;
}
protected QueryIterator execute(OpGraph opGraph, QueryIterator input)
{
QueryIterator qIter = specialcase(opGraph.getNode(), opGraph.getSubOp(), input) ;
if ( qIter != null )
return qIter ;
return new QueryIterGraph(input, opGraph, execCxt) ;
}
private QueryIterator specialcase(Node gn, Op subOp, QueryIterator input)
{
// This is a placeholder for code to specially handle explicitly named
// default graph and union graph.
if ( Quad.isDefaultGraph(gn) )
{
ExecutionContext cxt2 = new ExecutionContext(execCxt, execCxt.getDataset().getDefaultGraph()) ;
return execute(subOp, input, cxt2) ;
}
if ( true ) return null ;
if ( gn == Quad.unionGraph )
{}
/* Bad
if ( gn == Quad.tripleInQuad ) {}
*/
return null ;
}
protected QueryIterator execute(OpService opService, QueryIterator input)
{
return new QueryIterService(input, opService, execCxt) ;
}
// Quad form, "GRAPH ?g {}" Flip back to OpGraph.
// Normally quad stores override this.
protected QueryIterator execute(OpDatasetNames dsNames, QueryIterator input)
{
if ( false )
{
OpGraph op = new OpGraph(dsNames.getGraphNode(), new OpBGP()) ;
return execute(op, input) ;
}
throw new ARQNotImplemented("execute/OpDatasetNames") ;
}
protected QueryIterator execute(OpTable opTable, QueryIterator input)
{
// if ( input instanceof QueryIteratorBase )
// {
// String x = ((QueryIteratorBase)input).debug();
// System.out.println(x) ;
// }
//
if ( opTable.isJoinIdentity() )
return input ;
if ( input instanceof QueryIterRoot )
{
input.close() ;
return opTable.getTable().iterator(execCxt) ;
}
//throw new ARQNotImplemented("Not identity table") ;
QueryIterator qIterT = opTable.getTable().iterator(execCxt) ;
//QueryIterator qIterT = root() ;
QueryIterator qIter = new QueryIterJoin(input, qIterT, execCxt) ;
return qIter ;
}
protected QueryIterator execute(OpExt opExt, QueryIterator input)
{
try {
QueryIterator qIter = opExt.eval(input, execCxt) ;
if ( qIter != null )
return qIter ;
} catch (UnsupportedOperationException ex) { }
// null or UnsupportedOperationException
throw new QueryExecException("Encountered unsupported OpExt: "+opExt.getName()) ;
}
protected QueryIterator execute(OpLabel opLabel, QueryIterator input)
{
if ( ! opLabel.hasSubOp() )
return input ;
return executeOp(opLabel.getSubOp(), input) ;
}
protected QueryIterator execute(OpNull opNull, QueryIterator input)
{
// Loose the input.
input.close() ;
return new QueryIterNullIterator(execCxt) ;
}
protected QueryIterator execute(OpList opList, QueryIterator input)
{
return executeOp(opList.getSubOp(), input) ;
}
protected QueryIterator execute(OpOrder opOrder, QueryIterator input)
{
QueryIterator qIter = executeOp(opOrder.getSubOp(), input) ;
qIter = new QueryIterSort(qIter, opOrder.getConditions(), execCxt) ;
return qIter ;
}
protected QueryIterator execute(OpTopN opTop, QueryIterator input)
{
QueryIterator qIter = null ;
// We could also do (reduced) here as well.
// but it's detected in TrabsformTopN and turned into (distinct)
// there so that code catches that already.
// We leave this to do the strict case of (top N (distinct ...))
if ( opTop.getSubOp() instanceof OpDistinct ) {
OpDistinct opDistinct = (OpDistinct)opTop.getSubOp() ;
qIter = executeOp(opDistinct.getSubOp(), input) ;
qIter = new QueryIterTopN(qIter, opTop.getConditions(), opTop.getLimit(), true, execCxt) ;
} else {
qIter = executeOp(opTop.getSubOp(), input) ;
qIter = new QueryIterTopN(qIter, opTop.getConditions(), opTop.getLimit(), false, execCxt) ;
}
return qIter ;
}
protected QueryIterator execute(OpProject opProject, QueryIterator input)
{
// This may be under a (graph) in which case we need to operate
// the active graph.
// More intelligent QueryIterProject needed.
if ( input instanceof QueryIterRoot )
{
QueryIterator qIter = executeOp(opProject.getSubOp(), input) ;
qIter = new QueryIterProject(qIter, opProject.getVars(), execCxt) ;
return qIter ;
}
// Nested projected : need to ensure the input is seen.
// ROLL into QueryIterProject
QueryIterator qIter = new QueryIterProject2(opProject, input, this, execCxt) ;
return qIter ;
}
protected QueryIterator execute(OpSlice opSlice, QueryIterator input)
{
QueryIterator qIter = executeOp(opSlice.getSubOp(), input) ;
qIter = new QueryIterSlice(qIter, opSlice.getStart(), opSlice.getLength(), execCxt) ;
return qIter ;
}
protected QueryIterator execute(OpGroup opGroup, QueryIterator input)
{
QueryIterator qIter = executeOp(opGroup.getSubOp(), input) ;
qIter = new QueryIterGroup(qIter, opGroup.getGroupVars(), opGroup.getAggregators(), execCxt) ;
return qIter ;
}
protected QueryIterator execute(OpDistinct opDistinct, QueryIterator input)
{
QueryIterator qIter = executeOp(opDistinct.getSubOp(), input) ;
qIter = new QueryIterDistinct(qIter, execCxt) ;
return qIter ;
}
protected QueryIterator execute(OpReduced opReduced, QueryIterator input)
{
QueryIterator qIter = executeOp(opReduced.getSubOp(), input) ;
qIter = new QueryIterReduced(qIter, execCxt) ;
return qIter ;
}
protected QueryIterator execute(OpAssign opAssign, QueryIterator input)
{
// Need prepare?
QueryIterator qIter = executeOp(opAssign.getSubOp(), input) ;
qIter = new QueryIterAssign(qIter, opAssign.getVarExprList(), execCxt, false) ;
return qIter ;
}
protected QueryIterator execute(OpExtend opExtend, QueryIterator input)
{
// We know (parse time checking) the variable is unused so far in
// the query so we can use QueryIterAssign knowing that it behaves
// the same as extend. The boolean should only be a check.
QueryIterator qIter = executeOp(opExtend.getSubOp(), input) ;
qIter = new QueryIterAssign(qIter, opExtend.getVarExprList(), execCxt, true) ;
return qIter ;
}
public static QueryIterator createRootQueryIterator(ExecutionContext execCxt)
{
return QueryIterRoot.create(execCxt) ;
}
protected QueryIterator root()
{ return createRootQueryIterator(execCxt) ; }
// Use this to debug evaluation
// Example:
// input = debug(input) ;
private QueryIterator debug(String marker, QueryIterator input)
{
List<Binding> x = all(input) ;
for ( Binding b : x )
{
System.out.print(marker) ;
System.out.print(": ") ;
System.out.println(b) ;
}
return new QueryIterPlainWrapper(x.iterator(), execCxt) ;
}
private static List<Binding> all(QueryIterator input)
{
return Iter.toList(input) ;
}
}