import Analysis.CallGraph.*;
import IR.*;
import IR.Flat.*;
+import IR.Tree.Modifiers;
import java.util.*;
import java.io.*;
public class OwnershipAnalysis {
- ///////////////////////////////////////////
- //
- // Public interface to discover possible
- // aliases in the program under analysis
- //
- ///////////////////////////////////////////
- public HashSet<AllocationSite>
- getFlaggedAllocationSitesReachableFromTask( TaskDescriptor td ) {
- return getFlaggedAllocationSitesReachableFromTaskPRIVATE( td );
- }
+ ///////////////////////////////////////////
+ //
+ // Public interface to discover possible
+ // aliases in the program under analysis
+ //
+ ///////////////////////////////////////////
- public AllocationSite getAllocationSiteFromFlatNew( FlatNew fn ) {
- return getAllocationSiteFromFlatNewPRIVATE( fn );
- }
+ public HashSet<AllocationSite>
+ getFlaggedAllocationSitesReachableFromTask(TaskDescriptor td) {
+ return getFlaggedAllocationSitesReachableFromTaskPRIVATE(td);
+ }
- public boolean createsPotentialAliases( Descriptor taskOrMethod,
- int paramIndex1,
- int paramIndex2 ) {
+ public AllocationSite getAllocationSiteFromFlatNew(FlatNew fn) {
+ return getAllocationSiteFromFlatNewPRIVATE(fn);
+ }
- OwnershipGraph og = mapDescriptorToCompleteOwnershipGraph.get( taskOrMethod );
- assert( og != null );
+ public boolean createsPotentialAliases(Descriptor taskOrMethod,
+ int paramIndex1,
+ int paramIndex2) {
- return createsPotentialAliases( og,
- getHeapRegionIDset( og, paramIndex1 ),
- getHeapRegionIDset( og, paramIndex2 ) );
- }
+ OwnershipGraph og = mapDescriptorToCompleteOwnershipGraph.get(taskOrMethod);
+ assert(og != null);
+ return og.hasPotentialAlias(paramIndex1, paramIndex2);
+ }
- public boolean createsPotentialAliases( Descriptor taskOrMethod,
- int paramIndex,
- AllocationSite alloc ) {
+ public boolean createsPotentialAliases(Descriptor taskOrMethod,
+ int paramIndex,
+ AllocationSite alloc) {
- OwnershipGraph og = mapDescriptorToCompleteOwnershipGraph.get( taskOrMethod );
- assert( og != null );
+ OwnershipGraph og = mapDescriptorToCompleteOwnershipGraph.get(taskOrMethod);
+ assert(og != null);
+ return og.hasPotentialAlias(paramIndex, alloc);
+ }
- return createsPotentialAliases( og,
- getHeapRegionIDset( og, paramIndex ),
- getHeapRegionIDset( alloc ) );
- }
+ public boolean createsPotentialAliases(Descriptor taskOrMethod,
+ AllocationSite alloc,
+ int paramIndex) {
- public boolean createsPotentialAliases( Descriptor taskOrMethod,
- AllocationSite alloc,
- int paramIndex ) {
+ OwnershipGraph og = mapDescriptorToCompleteOwnershipGraph.get(taskOrMethod);
+ assert(og != null);
+ return og.hasPotentialAlias(paramIndex, alloc);
+ }
- OwnershipGraph og = mapDescriptorToCompleteOwnershipGraph.get( taskOrMethod );
- assert( og != null );
+ public boolean createsPotentialAliases(Descriptor taskOrMethod,
+ AllocationSite alloc1,
+ AllocationSite alloc2) {
- return createsPotentialAliases( og,
- getHeapRegionIDset( og, paramIndex ),
- getHeapRegionIDset( alloc ) );
- }
+ OwnershipGraph og = mapDescriptorToCompleteOwnershipGraph.get(taskOrMethod);
+ assert(og != null);
+ return og.hasPotentialAlias(alloc1, alloc2);
+ }
- public boolean createsPotentialAliases( Descriptor taskOrMethod,
- AllocationSite alloc1,
- AllocationSite alloc2 ) {
+ // use the methods given above to check every possible alias
+ // between task parameters and flagged allocation sites reachable
+ // from the task
+ public void writeAllAliases(String outputFile) throws java.io.IOException {
- OwnershipGraph og = mapDescriptorToCompleteOwnershipGraph.get( taskOrMethod );
- assert( og != null );
+ BufferedWriter bw = new BufferedWriter(new FileWriter(outputFile) );
- return createsPotentialAliases( og,
- getHeapRegionIDset( alloc1 ),
- getHeapRegionIDset( alloc2 ) );
- }
+ bw.write("Conducting ownership analysis with allocation depth = "+allocationDepth);
- public boolean createsPotentialAliases( Descriptor taskOrMethod,
- AllocationSite alloc,
- HashSet<AllocationSite> allocSet ) {
+ // look through every task for potential aliases
+ Iterator taskItr = state.getTaskSymbolTable().getDescriptorsIterator();
+ while( taskItr.hasNext() ) {
+ TaskDescriptor td = (TaskDescriptor) taskItr.next();
- OwnershipGraph og = mapDescriptorToCompleteOwnershipGraph.get( taskOrMethod );
- assert( og != null );
+ bw.write("\n---------"+td+"--------\n");
- return createsPotentialAliases( og,
- getHeapRegionIDset( alloc ),
- getHeapRegionIDset( allocSet ) );
- }
+ HashSet<AllocationSite> allocSites = getFlaggedAllocationSitesReachableFromTask(td);
- // use the methods given above to check every possible alias
- // between task parameters and flagged allocation sites reachable
- // from the task
- public void writeAllAliases( String outputFile ) throws java.io.IOException {
-
- BufferedWriter bw = new BufferedWriter( new FileWriter( outputFile ) );
-
- // look through every task for potential aliases
- Iterator taskItr = state.getTaskSymbolTable().getDescriptorsIterator();
- while( taskItr.hasNext() ) {
- TaskDescriptor td = (TaskDescriptor) taskItr.next();
-
- HashSet<AllocationSite> allocSites = getFlaggedAllocationSitesReachableFromTask( td );
-
- // for each task parameter, check for aliases with
- // other task parameters and every allocation site
- // reachable from this task
- FlatMethod fm = state.getMethodFlat( td );
- for( int i = 0; i < fm.numParameters(); ++i ) {
-
- // for the ith parameter check for aliases to all
- // higher numbered parameters
- for( int j = i + 1; j < fm.numParameters(); ++j ) {
- if( createsPotentialAliases( td, i, j ) ) {
- bw.write( "Task "+td+" potentially aliases parameters "+i+" and "+j+".\n" );
- }
- }
-
- // for the ith parameter, check for aliases against
- // the set of allocation sites reachable from this
- // task context
- Iterator allocItr = allocSites.iterator();
- while( allocItr.hasNext() ) {
- AllocationSite as = (AllocationSite) allocItr.next();
- if( createsPotentialAliases( td, i, as ) ) {
- bw.write( "Task "+td+" potentially aliases parameter "+i+" and "+as+".\n" );
- }
- }
- }
+ // for each task parameter, check for aliases with
+ // other task parameters and every allocation site
+ // reachable from this task
+ boolean foundSomeAlias = false;
- // for each allocation site check for aliases with
- // other allocation sites in the context of execution
- // of this task
- Iterator allocItr = allocSites.iterator();
- while( allocItr.hasNext() ) {
- AllocationSite as = (AllocationSite) allocItr.next();
- if( createsPotentialAliases( td, as, allocSites ) ) {
- bw.write( "Task "+td+" potentially aliases "+as+" and the rest of the set.\n" );
- }
- }
+ FlatMethod fm = state.getMethodFlat(td);
+ for( int i = 0; i < fm.numParameters(); ++i ) {
+
+ // for the ith parameter check for aliases to all
+ // higher numbered parameters
+ for( int j = i + 1; j < fm.numParameters(); ++j ) {
+ if( createsPotentialAliases(td, i, j) ) {
+ foundSomeAlias = true;
+ bw.write("Potential alias between parameters "+i+" and "+j+".\n");
+ }
}
- bw.close();
+ // for the ith parameter, check for aliases against
+ // the set of allocation sites reachable from this
+ // task context
+ Iterator allocItr = allocSites.iterator();
+ while( allocItr.hasNext() ) {
+ AllocationSite as = (AllocationSite) allocItr.next();
+ if( createsPotentialAliases(td, i, as) ) {
+ foundSomeAlias = true;
+ bw.write("Potential alias between parameter "+i+" and "+as.getFlatNew()+".\n");
+ }
+ }
+ }
+
+ // for each allocation site check for aliases with
+ // other allocation sites in the context of execution
+ // of this task
+ HashSet<AllocationSite> outerChecked = new HashSet<AllocationSite>();
+ Iterator allocItr1 = allocSites.iterator();
+ while( allocItr1.hasNext() ) {
+ AllocationSite as1 = (AllocationSite) allocItr1.next();
+
+ Iterator allocItr2 = allocSites.iterator();
+ while( allocItr2.hasNext() ) {
+ AllocationSite as2 = (AllocationSite) allocItr2.next();
+
+ if( !outerChecked.contains(as2) &&
+ createsPotentialAliases(td, as1, as2) ) {
+ foundSomeAlias = true;
+ bw.write("Potential alias between "+as1.getFlatNew()+" and "+as2.getFlatNew()+".\n");
+ }
+ }
+
+ outerChecked.add(as1);
+ }
+
+ if( !foundSomeAlias ) {
+ bw.write("No aliases between flagged objects in Task "+td+".\n");
+ }
}
- ///////////////////////////////////////////
- //
- // end public interface
- //
- ///////////////////////////////////////////
+ bw.close();
+ }
+ ///////////////////////////////////////////
+ //
+ // end public interface
+ //
+ ///////////////////////////////////////////
-
- // data from the compiler
- private State state;
- private CallGraph callGraph;
- private int allocationDepth;
- // used to identify HeapRegionNode objects
- // A unique ID equates an object in one
- // ownership graph with an object in another
- // graph that logically represents the same
- // heap region
- static private int uniqueIDcount = 0;
+ // data from the compiler
+ private State state;
+ private TypeUtil typeUtil;
+ private CallGraph callGraph;
+ private int allocationDepth;
- // Use these data structures to track progress of
- // processing all methods in the program, and by methods
- // TaskDescriptor and MethodDescriptor are combined
- // together, with a common parent class Descriptor
- private HashSet <Descriptor> descriptorsToVisit;
- private Hashtable<Descriptor, OwnershipGraph> mapDescriptorToCompleteOwnershipGraph;
- private Hashtable<FlatNew, AllocationSite> mapFlatNewToAllocationSite;
- private Hashtable<Descriptor, HashSet<AllocationSite> > mapDescriptorToAllocationSiteSet;
+ // used to identify HeapRegionNode objects
+ // A unique ID equates an object in one
+ // ownership graph with an object in another
+ // graph that logically represents the same
+ // heap region
+ // start at 10 and incerement to leave some
+ // reserved IDs for special purposes
+ static private int uniqueIDcount = 10;
- // Use these data structures to track progress of one pass of
- // processing the FlatNodes of a particular method
- private HashSet <FlatNode> flatNodesToVisit;
- private Hashtable<FlatNode, OwnershipGraph> mapFlatNodeToOwnershipGraph;
- private HashSet <FlatReturnNode> returnNodesToCombineForCompleteOwnershipGraph;
+ // Use these data structures to track progress of
+ // processing all methods in the program, and by methods
+ // TaskDescriptor and MethodDescriptor are combined
+ // together, with a common parent class Descriptor
+ private Hashtable<FlatMethod, OwnershipGraph> mapFlatMethodToInitialParamAllocGraph;
+ private Hashtable<Descriptor, OwnershipGraph> mapDescriptorToCompleteOwnershipGraph;
+ private Hashtable<FlatNew, AllocationSite> mapFlatNewToAllocationSite;
+ private Hashtable<Descriptor, HashSet<AllocationSite> > mapDescriptorToAllocationSiteSet;
+ private Hashtable<Descriptor, Integer> mapDescriptorToNumUpdates;
- // this analysis generates an ownership graph for every task
- // in the program
- public OwnershipAnalysis( State state,
- CallGraph callGraph,
- int allocationDepth ) throws java.io.IOException {
- this.state = state;
- this.callGraph = callGraph;
- this.allocationDepth = allocationDepth;
+ // Use these data structures to track progress of one pass of
+ // processing the FlatNodes of a particular method
+ private HashSet <FlatNode> flatNodesToVisit;
+ private Hashtable<FlatNode, OwnershipGraph> mapFlatNodeToOwnershipGraph;
+ private HashSet <FlatReturnNode> returnNodesToCombineForCompleteOwnershipGraph;
- descriptorsToVisit = new HashSet<Descriptor>();
+ // descriptorsToAnalyze identifies the set of tasks and methods
+ // that are reachable from the program tasks, this set is initialized
+ // and then remains static
+ private HashSet<Descriptor> descriptorsToAnalyze;
- mapDescriptorToCompleteOwnershipGraph =
- new Hashtable<Descriptor, OwnershipGraph>();
+ // descriptorsToVisit is initialized to descriptorsToAnalyze and is
+ // reduced by visiting a descriptor during analysis. When dependents
+ // must be scheduled, only those contained in descriptorsToAnalyze
+ // should be re-added to this set
+ private HashSet<Descriptor> descriptorsToVisit;
- mapFlatNewToAllocationSite =
- new Hashtable<FlatNew, AllocationSite>();
+ // a special field descriptor for all array elements
+ private static FieldDescriptor fdElement = new FieldDescriptor(new Modifiers(Modifiers.PUBLIC),
+ new TypeDescriptor("Array[]"),
+ "elements",
+ null,
+ false);
+ // for controlling DOT file output
+ private boolean writeDOTs;
+ private boolean writeAllDOTs;
- mapDescriptorToAllocationSiteSet =
- new Hashtable<Descriptor, HashSet<AllocationSite> >();
- // use this set to prevent infinite recursion when
- // traversing the call graph
- HashSet<Descriptor> calleesScheduled = new HashSet<Descriptor>();
- // initialize methods to visit as the set of all tasks in the
- // program and then any method that could be called starting
- // from those tasks
- Iterator taskItr = state.getTaskSymbolTable().getDescriptorsIterator();
- while( taskItr.hasNext() ) {
- Descriptor d = (Descriptor) taskItr.next();
- descriptorsToVisit.add( d );
+ // this analysis generates an ownership graph for every task
+ // in the program
+ public OwnershipAnalysis(State state,
+ TypeUtil tu,
+ CallGraph callGraph,
+ int allocationDepth,
+ boolean writeDOTs,
+ boolean writeAllDOTs,
+ String aliasFile) throws java.io.IOException {
- // recursively find all callees from this task
- scheduleAllCallees( calleesScheduled, d );
- }
-
- // as mentioned above, analyze methods one-by-one, possibly revisiting
- // a method if the methods that it calls are updated
- analyzeMethods();
- }
+ this.state = state;
+ this.typeUtil = tu;
+ this.callGraph = callGraph;
+ this.allocationDepth = allocationDepth;
+ this.writeDOTs = writeDOTs;
+ this.writeAllDOTs = writeAllDOTs;
- // called from the constructor to help initialize the set
- // of methods that needs to be analyzed by ownership analysis
- private void scheduleAllCallees( HashSet<Descriptor> calleesScheduled,
- Descriptor d ) {
- if( calleesScheduled.contains( d ) ) {
- return;
- }
- calleesScheduled.add( d );
+ descriptorsToAnalyze = new HashSet<Descriptor>();
- Set callees = callGraph.getCalleeSet( d );
- if( callees == null ) {
- return;
- }
+ mapFlatMethodToInitialParamAllocGraph =
+ new Hashtable<FlatMethod, OwnershipGraph>();
- Iterator methItr = callees.iterator();
- while( methItr.hasNext() ) {
- MethodDescriptor md = (MethodDescriptor) methItr.next();
- descriptorsToVisit.add( md );
+ mapDescriptorToCompleteOwnershipGraph =
+ new Hashtable<Descriptor, OwnershipGraph>();
- // recursively find all callees from this task
- scheduleAllCallees( calleesScheduled, md );
- }
+ mapFlatNewToAllocationSite =
+ new Hashtable<FlatNew, AllocationSite>();
+
+ mapDescriptorToAllocationSiteSet =
+ new Hashtable<Descriptor, HashSet<AllocationSite> >();
+
+ if( writeAllDOTs ) {
+ mapDescriptorToNumUpdates = new Hashtable<Descriptor, Integer>();
}
+ // initialize methods to visit as the set of all tasks in the
+ // program and then any method that could be called starting
+ // from those tasks
+ Iterator taskItr = state.getTaskSymbolTable().getDescriptorsIterator();
+ while( taskItr.hasNext() ) {
+ Descriptor d = (Descriptor) taskItr.next();
+ scheduleAllCallees(d);
+ }
- // manage the set of tasks and methods to be analyzed
- // and be sure to reschedule tasks/methods when the methods
- // they call are updated
- private void analyzeMethods() throws java.io.IOException {
-
- while( !descriptorsToVisit.isEmpty() ) {
- Descriptor d = (Descriptor) descriptorsToVisit.iterator().next();
- descriptorsToVisit.remove( d );
-
- // because the task or method descriptor just extracted
- // was in the "to visit" set it either hasn't been analyzed
- // yet, or some method that it depends on has been
- // updated. Recompute a complete ownership graph for
- // this task/method and compare it to any previous result.
- // If there is a change detected, add any methods/tasks
- // that depend on this one to the "to visit" set.
-
- System.out.println( "Analyzing " + d );
-
- FlatMethod fm;
- if( d instanceof MethodDescriptor ) {
- fm = state.getMethodFlat( (MethodDescriptor) d );
- } else {
- assert d instanceof TaskDescriptor;
- fm = state.getMethodFlat( (TaskDescriptor) d );
- }
-
- OwnershipGraph og = analyzeFlatMethod( d, fm );
- OwnershipGraph ogPrev = mapDescriptorToCompleteOwnershipGraph.get( d );
-
- if( !og.equals( ogPrev ) ) {
- mapDescriptorToCompleteOwnershipGraph.put( d, og );
-
- og.writeGraph( d, false, false );
-
- // only methods have dependents, tasks cannot
- // be invoked by any user program calls
- if( d instanceof MethodDescriptor ) {
- MethodDescriptor md = (MethodDescriptor) d;
- Set dependents = callGraph.getCallerSet( md );
- if( dependents != null ) {
- descriptorsToVisit.addAll( dependents );
- }
- }
- }
- }
+ // before beginning analysis, initialize every scheduled method
+ // with an ownership graph that has populated parameter index tables
+ // by analyzing the first node which is always a FlatMethod node
+ Iterator<Descriptor> dItr = descriptorsToAnalyze.iterator();
+ while( dItr.hasNext() ) {
+ Descriptor d = dItr.next();
+ OwnershipGraph og = new OwnershipGraph(allocationDepth, typeUtil);
+
+ FlatMethod fm;
+ if( d instanceof MethodDescriptor ) {
+ fm = state.getMethodFlat( (MethodDescriptor) d);
+ } else {
+ assert d instanceof TaskDescriptor;
+ fm = state.getMethodFlat( (TaskDescriptor) d);
+ }
+
+ System.out.println("Previsiting " + d);
+
+ og = analyzeFlatNode(d, fm, null, og);
+ setGraphForDescriptor(d, og);
+ }
+ System.out.println("");
+
+ // as mentioned above, analyze methods one-by-one, possibly revisiting
+ // a method if the methods that it calls are updated
+ analyzeMethods();
+
+ System.out.println("");
+
+ if( aliasFile != null ) {
+ writeAllAliases(aliasFile);
}
+ }
+ // called from the constructor to help initialize the set
+ // of methods that needs to be analyzed by ownership analysis
+ private void scheduleAllCallees(Descriptor d) {
+ if( descriptorsToAnalyze.contains(d) ) {
+ return;
+ }
+ descriptorsToAnalyze.add(d);
- // keep passing the Descriptor of the method along for debugging
- // and dot file writing
- private OwnershipGraph
- analyzeFlatMethod( Descriptor mDesc,
- FlatMethod flatm ) throws java.io.IOException {
+ // start with all method calls to further schedule
+ Set moreMethodsToCheck = moreMethodsToCheck = callGraph.getMethodCalls(d);
- // initialize flat nodes to visit as the flat method
- // because all other nodes in this flat method are
- // decendents of the flat method itself
- flatNodesToVisit = new HashSet<FlatNode>();
- flatNodesToVisit.add( flatm );
+ if( d instanceof MethodDescriptor ) {
+ // see if this method has virtual dispatch
+ Set virtualMethods = callGraph.getMethods( (MethodDescriptor)d);
+ moreMethodsToCheck.addAll(virtualMethods);
+ }
- // initilize the mapping of flat nodes in this flat method to
- // ownership graph results to an empty mapping
- mapFlatNodeToOwnershipGraph = new Hashtable<FlatNode, OwnershipGraph>();
+ // keep following any further methods identified in
+ // the call chain
+ Iterator methItr = moreMethodsToCheck.iterator();
+ while( methItr.hasNext() ) {
+ Descriptor m = (Descriptor) methItr.next();
+ scheduleAllCallees(m);
+ }
+ }
- // initialize the set of return nodes that will be combined as
- // the final ownership graph result to return as an empty set
- returnNodesToCombineForCompleteOwnershipGraph = new HashSet<FlatReturnNode>();
+ // manage the set of tasks and methods to be analyzed
+ // and be sure to reschedule tasks/methods when the methods
+ // they call are updated
+ private void analyzeMethods() throws java.io.IOException {
- // DEBUG
- //int x = 0;
+ descriptorsToVisit = (HashSet<Descriptor>)descriptorsToAnalyze.clone();
+ while( !descriptorsToVisit.isEmpty() ) {
+ Descriptor d = (Descriptor) descriptorsToVisit.iterator().next();
+ descriptorsToVisit.remove(d);
- while( !flatNodesToVisit.isEmpty() ) {
- FlatNode fn = (FlatNode) flatNodesToVisit.iterator().next();
- flatNodesToVisit.remove( fn );
+ // because the task or method descriptor just extracted
+ // was in the "to visit" set it either hasn't been analyzed
+ // yet, or some method that it depends on has been
+ // updated. Recompute a complete ownership graph for
+ // this task/method and compare it to any previous result.
+ // If there is a change detected, add any methods/tasks
+ // that depend on this one to the "to visit" set.
- // perform this node's contributions to the ownership
- // graph on a new copy, then compare it to the old graph
- // at this node to see if anything was updated.
- OwnershipGraph og = new OwnershipGraph( allocationDepth );
+ System.out.println("Analyzing " + d);
- // start by merging all node's parents' graphs
- for( int i = 0; i < fn.numPrev(); ++i ) {
- FlatNode pn = fn.getPrev( i );
- OwnershipGraph ogParent = getGraphFromFlatNode( pn );
- og.merge( ogParent );
- }
-
- // apply the analysis of the flat node to the
- // ownership graph made from the merge of the
- // parent graphs
- analyzeFlatNode( mDesc,
- fn,
- returnNodesToCombineForCompleteOwnershipGraph,
- og );
-
- // if the results of the new graph are different from
- // the current graph at this node, replace the graph
- // with the update and enqueue the children for
- // processing
- OwnershipGraph ogPrev = getGraphFromFlatNode( fn );
-
- if( !og.equals( ogPrev ) ) {
- setGraphForFlatNode( fn, og );
-
- // DEBUG
- /*
- ++x;
-
- if( x > 5000 ) {
- String s = String.format( "%04d", x );
- og.writeGraph( "debug"+s, false, false );
- }
-
- if( x == 5020 ) {
- System.exit( -1 );
- }
- */
-
- for( int i = 0; i < fn.numNext(); i++ ) {
- FlatNode nn = fn.getNext( i );
- flatNodesToVisit.add( nn );
- }
- }
- }
+ FlatMethod fm;
+ if( d instanceof MethodDescriptor ) {
+ fm = state.getMethodFlat( (MethodDescriptor) d);
+ } else {
+ assert d instanceof TaskDescriptor;
+ fm = state.getMethodFlat( (TaskDescriptor) d);
+ }
- // end by merging all return nodes into a complete
- // ownership graph that represents all possible heap
- // states after the flat method returns
- OwnershipGraph completeGraph = new OwnershipGraph( allocationDepth );
- Iterator retItr = returnNodesToCombineForCompleteOwnershipGraph.iterator();
- while( retItr.hasNext() ) {
- FlatReturnNode frn = (FlatReturnNode) retItr.next();
- OwnershipGraph ogr = getGraphFromFlatNode( frn );
- completeGraph.merge( ogr );
+ OwnershipGraph og = analyzeFlatMethod(d, fm);
+ OwnershipGraph ogPrev = mapDescriptorToCompleteOwnershipGraph.get(d);
+ if( !og.equals(ogPrev) ) {
+ setGraphForDescriptor(d, og);
+
+ // only methods have dependents, tasks cannot
+ // be invoked by any user program calls
+ if( d instanceof MethodDescriptor ) {
+ MethodDescriptor md = (MethodDescriptor) d;
+ Set dependents = callGraph.getCallerSet(md);
+ if( dependents != null ) {
+ Iterator depItr = dependents.iterator();
+ while( depItr.hasNext() ) {
+ Descriptor dependent = (Descriptor) depItr.next();
+ if( descriptorsToAnalyze.contains(dependent) ) {
+ descriptorsToVisit.add(dependent);
+ }
+ }
+ }
}
- return completeGraph;
+ }
}
+ }
- private void
- analyzeFlatNode( Descriptor methodDesc,
- FlatNode fn,
- HashSet<FlatReturnNode> setRetNodes,
- OwnershipGraph og ) throws java.io.IOException {
-
- TempDescriptor src;
- TempDescriptor dst;
- FieldDescriptor fld;
-
- // use node type to decide what alterations to make
- // to the ownership graph
- switch( fn.kind() ) {
-
- case FKind.FlatMethod:
- FlatMethod fm = (FlatMethod) fn;
-
- // there should only be one FlatMethod node as the
- // parent of all other FlatNode objects, so take
- // the opportunity to construct the initial graph by
- // adding parameters labels to new heap regions
- for( int i = 0; i < fm.numParameters(); ++i ) {
- TempDescriptor tdParam = fm.getParameter( i );
- og.assignTempToParameterAllocation( methodDesc instanceof TaskDescriptor,
- tdParam,
- new Integer( i ) );
- }
- break;
+ // keep passing the Descriptor of the method along for debugging
+ // and dot file writing
+ private OwnershipGraph
+ analyzeFlatMethod(Descriptor mDesc,
+ FlatMethod flatm) throws java.io.IOException {
- case FKind.FlatOpNode:
- FlatOpNode fon = (FlatOpNode) fn;
- if( fon.getOp().getOp() == Operation.ASSIGN ) {
- src = fon.getLeft();
- dst = fon.getDest();
- og.assignTempToTemp( src, dst );
- }
- break;
-
- case FKind.FlatFieldNode:
- FlatFieldNode ffn = (FlatFieldNode) fn;
- src = ffn.getSrc();
- dst = ffn.getDst();
- fld = ffn.getField();
- if( !fld.getType().isPrimitive() ) {
- og.assignTempToField( src, dst, fld );
- }
- break;
-
- case FKind.FlatSetFieldNode:
- FlatSetFieldNode fsfn = (FlatSetFieldNode) fn;
- src = fsfn.getSrc();
- dst = fsfn.getDst();
- fld = fsfn.getField();
- og.assignFieldToTemp( src, dst, fld );
- break;
-
- case FKind.FlatNew:
- FlatNew fnn = (FlatNew) fn;
- dst = fnn.getDst();
- AllocationSite as = getAllocationSiteFromFlatNewPRIVATE( fnn );
-
- og.assignTempToNewAllocation( dst, as );
- break;
-
- case FKind.FlatCall:
- FlatCall fc = (FlatCall) fn;
- MethodDescriptor md = fc.getMethod();
- FlatMethod flatm = state.getMethodFlat( md );
- //HashSet<AllocationSite> allocSiteSet = getAllocationSiteSet( md );
- OwnershipGraph ogAllPossibleCallees = new OwnershipGraph( allocationDepth );
-
- if( md.isStatic() ) {
- // a static method is simply always the same, makes life easy
- OwnershipGraph onlyPossibleCallee = mapDescriptorToCompleteOwnershipGraph.get( md );
- ogAllPossibleCallees.merge( onlyPossibleCallee );
-
- /*
- if( onlyPossibleCallee != null ) {
- onlyPossibleCallee.writeGraph( "only", false, false );
- System.out.println( "There was only one possible callee, "+md );
- }
- */
-
- } else {
- // if the method descriptor is virtual, then there could be a
- // set of possible methods that will actually be invoked, so
- // find all of them and merge all of their graphs together
- TypeDescriptor typeDesc = fc.getThis().getType();
- Set possibleCallees = callGraph.getMethods( md, typeDesc );
-
- //int j = 0;
-
- Iterator i = possibleCallees.iterator();
- while( i.hasNext() ) {
- MethodDescriptor possibleMd = (MethodDescriptor) i.next();
- //allocSiteSet.addAll( getAllocationSiteSet( possibleMd ) );
- OwnershipGraph ogPotentialCallee = mapDescriptorToCompleteOwnershipGraph.get( possibleMd );
-
- /*
- if( ogPotentialCallee != null ) {
- ogPotentialCallee.writeGraph( "potential"+j, false, false );
- ++j;
- }
- */
-
- ogAllPossibleCallees.merge( ogPotentialCallee );
- }
-
- //System.out.println( "There were "+j+" potential callees merged together." );
- }
+ // initialize flat nodes to visit as the flat method
+ // because all other nodes in this flat method are
+ // decendents of the flat method itself
- //System.out.println( "AllocationSiteSet has "+allocSiteSet.size()+" items." );
-
- // now we should have the following information to resolve this method call:
- //
- // 1. A FlatCall fc to query for the caller's context (argument labels, etc)
- //
- // 2. Whether the method is static; if not we need to deal with the "this" pointer
- //
- // *******************************************************************************************
- // 3. The original FlatMethod flatm to query for callee's context (paramter labels)
- // NOTE! I assume FlatMethod before virtual dispatch accurately describes all possible methods!
- // *******************************************************************************************
- //
- // 4. The OwnershipGraph ogAllPossibleCallees is a merge of every ownership graph of all the possible
- // methods to capture any possible references made.
- //
- // 5. The Set of AllocationSite objects, allocSiteSet that is the set of allocation sites from
- // every possible method we might have chosen
- //
- og.resolveMethodCall( fc, md.isStatic(), flatm, ogAllPossibleCallees );
-
- //og.writeGraph( methodDesc, fn );
- break;
-
- case FKind.FlatReturnNode:
- FlatReturnNode frn = (FlatReturnNode) fn;
- setRetNodes.add( frn );
- //og.writeGraph( methodDesc, fn );
- break;
- }
- }
+ flatNodesToVisit = new HashSet<FlatNode>();
+ flatNodesToVisit.add(flatm);
+
+ // initilize the mapping of flat nodes in this flat method to
+ // ownership graph results to an empty mapping
+ mapFlatNodeToOwnershipGraph = new Hashtable<FlatNode, OwnershipGraph>();
+
+ // initialize the set of return nodes that will be combined as
+ // the final ownership graph result to return as an empty set
+ returnNodesToCombineForCompleteOwnershipGraph = new HashSet<FlatReturnNode>();
- static public Integer generateUniqueHeapRegionNodeID() {
- ++uniqueIDcount;
- return new Integer( uniqueIDcount );
- }
+ while( !flatNodesToVisit.isEmpty() ) {
+ FlatNode fn = (FlatNode) flatNodesToVisit.iterator().next();
+ flatNodesToVisit.remove(fn);
+ //System.out.println( " "+fn );
- private OwnershipGraph getGraphFromFlatNode( FlatNode fn ) {
- if( !mapFlatNodeToOwnershipGraph.containsKey( fn ) ) {
- mapFlatNodeToOwnershipGraph.put( fn, new OwnershipGraph( allocationDepth ) );
+ // perform this node's contributions to the ownership
+ // graph on a new copy, then compare it to the old graph
+ // at this node to see if anything was updated.
+ OwnershipGraph og = new OwnershipGraph(allocationDepth, typeUtil);
+
+ // start by merging all node's parents' graphs
+ for( int i = 0; i < fn.numPrev(); ++i ) {
+ FlatNode pn = fn.getPrev(i);
+ if( mapFlatNodeToOwnershipGraph.containsKey(pn) ) {
+ OwnershipGraph ogParent = mapFlatNodeToOwnershipGraph.get(pn);
+ og.merge(ogParent);
}
+ }
- return mapFlatNodeToOwnershipGraph.get( fn );
- }
+ // apply the analysis of the flat node to the
+ // ownership graph made from the merge of the
+ // parent graphs
+ og = analyzeFlatNode(mDesc,
+ fn,
+ returnNodesToCombineForCompleteOwnershipGraph,
+ og);
- private void setGraphForFlatNode( FlatNode fn, OwnershipGraph og ) {
- mapFlatNodeToOwnershipGraph.put( fn, og );
- }
+ //debugSnapshot(og,fn);
-
+ // if the results of the new graph are different from
+ // the current graph at this node, replace the graph
+ // with the update and enqueue the children for
+ // processing
+ OwnershipGraph ogPrev = mapFlatNodeToOwnershipGraph.get(fn);
+ if( !og.equals(ogPrev) ) {
+ mapFlatNodeToOwnershipGraph.put(fn, og);
- // return just the allocation site associated with one FlatNew node
- private AllocationSite getAllocationSiteFromFlatNewPRIVATE( FlatNew fn ) {
- if( !mapFlatNewToAllocationSite.containsKey( fn ) ) {
- AllocationSite as = new AllocationSite( allocationDepth, fn.getType() );
+ for( int i = 0; i < fn.numNext(); i++ ) {
+ FlatNode nn = fn.getNext(i);
+ flatNodesToVisit.add(nn);
+ }
+ }
+ }
- // the newest nodes are single objects
- for( int i = 0; i < allocationDepth; ++i ) {
- Integer id = generateUniqueHeapRegionNodeID();
- as.setIthOldest( i, id );
- }
+ // end by merging all return nodes into a complete
+ // ownership graph that represents all possible heap
+ // states after the flat method returns
+ OwnershipGraph completeGraph = new OwnershipGraph(allocationDepth, typeUtil);
+ Iterator retItr = returnNodesToCombineForCompleteOwnershipGraph.iterator();
+ while( retItr.hasNext() ) {
+ FlatReturnNode frn = (FlatReturnNode) retItr.next();
+ assert mapFlatNodeToOwnershipGraph.containsKey(frn);
+ OwnershipGraph ogr = mapFlatNodeToOwnershipGraph.get(frn);
+ completeGraph.merge(ogr);
+ }
+
+ return completeGraph;
+ }
+
+
+ private OwnershipGraph
+ analyzeFlatNode(Descriptor methodDesc,
+ FlatNode fn,
+ HashSet<FlatReturnNode> setRetNodes,
+ OwnershipGraph og) throws java.io.IOException {
+
+ TempDescriptor lhs;
+ TempDescriptor rhs;
+ FieldDescriptor fld;
+
+ // use node type to decide what alterations to make
+ // to the ownership graph
+ switch( fn.kind() ) {
+
+ case FKind.FlatMethod:
+ FlatMethod fm = (FlatMethod) fn;
+
+ // there should only be one FlatMethod node as the
+ // parent of all other FlatNode objects, so take
+ // the opportunity to construct the initial graph by
+ // adding parameters labels to new heap regions
+ // AND this should be done once globally so that the
+ // parameter IDs are consistent between analysis
+ // iterations, so if this step has been done already
+ // just merge in the cached version
+ OwnershipGraph ogInitParamAlloc = mapFlatMethodToInitialParamAllocGraph.get(fm);
+ if( ogInitParamAlloc == null ) {
+
+ // analyze this node one time globally
+ for( int i = 0; i < fm.numParameters(); ++i ) {
+ TempDescriptor tdParam = fm.getParameter(i);
+ og.assignTempEqualToParamAlloc(tdParam,
+ methodDesc instanceof TaskDescriptor,
+ new Integer(i) );
+ }
+
+ // then remember it
+ OwnershipGraph ogResult = new OwnershipGraph(allocationDepth, typeUtil);
+ ogResult.merge(og);
+ mapFlatMethodToInitialParamAllocGraph.put(fm, ogResult);
+
+ } else {
+ // or just leverage the cached copy
+ og.merge(ogInitParamAlloc);
+ }
+ break;
+
+ case FKind.FlatOpNode:
+ FlatOpNode fon = (FlatOpNode) fn;
+ if( fon.getOp().getOp() == Operation.ASSIGN ) {
+ lhs = fon.getDest();
+ rhs = fon.getLeft();
+ og.assignTempXEqualToTempY(lhs, rhs);
+ }
+ break;
+
+ case FKind.FlatFieldNode:
+ FlatFieldNode ffn = (FlatFieldNode) fn;
+ lhs = ffn.getDst();
+ rhs = ffn.getSrc();
+ fld = ffn.getField();
+ if( !fld.getType().isImmutable() ) {
+ og.assignTempXEqualToTempYFieldF(lhs, rhs, fld);
+ }
+ break;
+
+ case FKind.FlatSetFieldNode:
+ FlatSetFieldNode fsfn = (FlatSetFieldNode) fn;
+ lhs = fsfn.getDst();
+ fld = fsfn.getField();
+ rhs = fsfn.getSrc();
+ if( !fld.getType().isImmutable() ) {
+ og.assignTempXFieldFEqualToTempY(lhs, fld, rhs);
+ }
+ break;
+
+ case FKind.FlatElementNode:
+ FlatElementNode fen = (FlatElementNode) fn;
+ lhs = fen.getDst();
+ rhs = fen.getSrc();
+ if( !lhs.getType().isImmutable() ) {
+ og.assignTempXEqualToTempYFieldF(lhs, rhs, fdElement);
+ }
+ break;
+
+ case FKind.FlatSetElementNode:
+ FlatSetElementNode fsen = (FlatSetElementNode) fn;
+ lhs = fsen.getDst();
+ rhs = fsen.getSrc();
+ if( !rhs.getType().isImmutable() ) {
+ og.assignTempXFieldFEqualToTempY(lhs, fdElement, rhs);
+ }
+ break;
+
+ case FKind.FlatNew:
+ FlatNew fnn = (FlatNew) fn;
+ lhs = fnn.getDst();
+ if( !lhs.getType().isImmutable() ) {
+ AllocationSite as = getAllocationSiteFromFlatNewPRIVATE(fnn);
+ og.assignTempEqualToNewAlloc(lhs, as);
+ }
+ break;
+
+ case FKind.FlatCall:
+ FlatCall fc = (FlatCall) fn;
+ MethodDescriptor md = fc.getMethod();
+ FlatMethod flatm = state.getMethodFlat(md);
+ OwnershipGraph ogMergeOfAllPossibleCalleeResults = new OwnershipGraph(allocationDepth, typeUtil);
+
+ if( md.isStatic() ) {
+ // a static method is simply always the same, makes life easy
+ OwnershipGraph onlyPossibleCallee = mapDescriptorToCompleteOwnershipGraph.get(md);
+ ogMergeOfAllPossibleCalleeResults = og;
+ ogMergeOfAllPossibleCalleeResults.resolveMethodCall(fc, md.isStatic(), flatm, onlyPossibleCallee);
+ } else {
+ // if the method descriptor is virtual, then there could be a
+ // set of possible methods that will actually be invoked, so
+ // find all of them and merge all of their results together
+ TypeDescriptor typeDesc = fc.getThis().getType();
+ Set possibleCallees = callGraph.getMethods(md, typeDesc);
+
+ Iterator i = possibleCallees.iterator();
+ while( i.hasNext() ) {
+ MethodDescriptor possibleMd = (MethodDescriptor) i.next();
- // the oldest node is a summary node
- Integer idSummary = generateUniqueHeapRegionNodeID();
- as.setSummary( idSummary );
+ // don't alter the working graph (og) until we compute a result for every
+ // possible callee, merge them all together, then set og to that
+ OwnershipGraph ogCopy = new OwnershipGraph(allocationDepth, typeUtil);
+ ogCopy.merge(og);
- mapFlatNewToAllocationSite.put( fn, as );
+ OwnershipGraph ogPotentialCallee = mapDescriptorToCompleteOwnershipGraph.get(possibleMd);
+ ogCopy.resolveMethodCall(fc, md.isStatic(), flatm, ogPotentialCallee);
+ ogMergeOfAllPossibleCalleeResults.merge(ogCopy);
}
+ }
+
+ og = ogMergeOfAllPossibleCalleeResults;
+ break;
+
+ case FKind.FlatReturnNode:
+ FlatReturnNode frn = (FlatReturnNode) fn;
+ rhs = frn.getReturnTemp();
+ if( rhs != null && !rhs.getType().isImmutable() ) {
+ og.assignReturnEqualToTemp(rhs);
+ }
+ setRetNodes.add(frn);
+ break;
+ }
- return mapFlatNewToAllocationSite.get( fn );
+ return og;
+ }
+
+
+ // insert a call to debugSnapshot() somewhere in the analysis to get
+ // successive captures of the analysis state
+ int debugCounter = 0;
+ int numStartCountReport = 0;
+ int freqCountReport = 1000;
+ int iterStartCapture = 20000;
+ int numIterToCapture = 400;
+ void debugSnapshot( OwnershipGraph og, FlatNode fn ) {
+ ++debugCounter;
+ if( debugCounter > numStartCountReport &&
+ debugCounter % freqCountReport == 0 ) {
+ System.out.println( " @@@ debug counter = "+debugCounter );
+ }
+ if( debugCounter > iterStartCapture ) {
+ System.out.println( " @@@ capturing debug "+(debugCounter-iterStartCapture)+" @@@" );
+ String graphName = String.format("snap%04d",debugCounter-iterStartCapture);
+ if( fn != null ) {
+ graphName = graphName+fn;
+ }
+ try {
+ og.writeGraph( graphName, true, true, false, false, false );
+ } catch( Exception e ) {
+ System.out.println( "Error writing debug capture." );
+ System.exit( 0 );
+ }
+ }
+ if( debugCounter == iterStartCapture + numIterToCapture ) {
+ System.out.println( "Stopping analysis after debug captures." );
+ System.exit( 0 );
}
+ }
- // return all allocation sites in the method (there is one allocation
- // site per FlatNew node in a method)
- private HashSet<AllocationSite> getAllocationSiteSet( Descriptor d ) {
- if( !mapDescriptorToAllocationSiteSet.containsKey( d ) ) {
- buildAllocationSiteSet( d );
- }
- return mapDescriptorToAllocationSiteSet.get( d );
+ // this method should generate integers strictly greater than zero!
+ // special "shadow" regions are made from a heap region by negating
+ // the ID
+ static public Integer generateUniqueHeapRegionNodeID() {
+ ++uniqueIDcount;
+ return new Integer(uniqueIDcount);
+ }
- }
- private void buildAllocationSiteSet( Descriptor d ) {
- HashSet<AllocationSite> s = new HashSet<AllocationSite>();
+ private void setGraphForDescriptor(Descriptor d, OwnershipGraph og)
+ throws IOException {
- FlatMethod fm;
- if( d instanceof MethodDescriptor ) {
- fm = state.getMethodFlat( (MethodDescriptor) d );
- } else {
- assert d instanceof TaskDescriptor;
- fm = state.getMethodFlat( (TaskDescriptor) d );
+ mapDescriptorToCompleteOwnershipGraph.put(d, og);
+
+ // arguments to writeGraph are:
+ // boolean writeLabels,
+ // boolean labelSelect,
+ // boolean pruneGarbage,
+ // boolean writeReferencers
+ // boolean writeParamMappings
+
+ if( writeDOTs ) {
+
+ if( !writeAllDOTs ) {
+ og.writeGraph(d, true, true, true, false, false);
+
+ } else {
+ if( !mapDescriptorToNumUpdates.containsKey(d) ) {
+ mapDescriptorToNumUpdates.put(d, new Integer(0) );
}
+ Integer n = mapDescriptorToNumUpdates.get(d);
+ og.writeGraph(d, n, true, true, true, false, false);
+ mapDescriptorToNumUpdates.put(d, n + 1);
+ }
+ }
+ }
- // visit every node in this FlatMethod's IR graph
- // and make a set of the allocation sites from the
- // FlatNew node's visited
- HashSet<FlatNode> visited = new HashSet<FlatNode>();
- HashSet<FlatNode> toVisit = new HashSet<FlatNode>();
- toVisit.add( fm );
- while( !toVisit.isEmpty() ) {
- FlatNode n = toVisit.iterator().next();
+ // return just the allocation site associated with one FlatNew node
+ private AllocationSite getAllocationSiteFromFlatNewPRIVATE(FlatNew fn) {
- if( n instanceof FlatNew ) {
- s.add( getAllocationSiteFromFlatNewPRIVATE( (FlatNew) n ) );
- }
+ if( !mapFlatNewToAllocationSite.containsKey(fn) ) {
+ AllocationSite as = new AllocationSite(allocationDepth, fn );
- toVisit.remove( n );
- visited.add( n );
+ // the newest nodes are single objects
+ for( int i = 0; i < allocationDepth; ++i ) {
+ Integer id = generateUniqueHeapRegionNodeID();
+ as.setIthOldest(i, id);
+ }
- for( int i = 0; i < n.numNext(); ++i ) {
- FlatNode child = n.getNext( i );
- if( !visited.contains( child ) ) {
- toVisit.add( child );
- }
- }
- }
+ // the oldest node is a summary node
+ Integer idSummary = generateUniqueHeapRegionNodeID();
+ as.setSummary(idSummary);
- mapDescriptorToAllocationSiteSet.put( d, s );
+ mapFlatNewToAllocationSite.put(fn, as);
}
+ return mapFlatNewToAllocationSite.get(fn);
+ }
- private HashSet<AllocationSite>
- getFlaggedAllocationSitesReachableFromTaskPRIVATE( TaskDescriptor td ) {
-
- HashSet<AllocationSite> asSetTotal = new HashSet<AllocationSite>();
- HashSet<Descriptor> toVisit = new HashSet<Descriptor>();
- HashSet<Descriptor> visited = new HashSet<Descriptor>();
-
- toVisit.add( td );
-
- // traverse this task and all methods reachable from this task
- while( !toVisit.isEmpty() ) {
- Descriptor d = toVisit.iterator().next();
- toVisit.remove( d );
- visited.add( d );
-
- HashSet<AllocationSite> asSet = getAllocationSiteSet( d );
- Iterator asItr = asSet.iterator();
- while( asItr.hasNext() ) {
- AllocationSite as = (AllocationSite) asItr.next();
- if( as.getType().getClassDesc().hasFlags() ) {
- asSetTotal.add( as );
- }
- }
-
- // enqueue callees of this method to be searched for
- // allocation sites also
- Set callees = callGraph.getCalleeSet( d );
- if( callees != null ) {
- Iterator methItr = callees.iterator();
- while( methItr.hasNext() ) {
- MethodDescriptor md = (MethodDescriptor) methItr.next();
-
- if( !visited.contains( md ) ) {
- toVisit.add( md );
- }
- }
- }
- }
-
- return asSetTotal;
+ // return all allocation sites in the method (there is one allocation
+ // site per FlatNew node in a method)
+ private HashSet<AllocationSite> getAllocationSiteSet(Descriptor d) {
+ if( !mapDescriptorToAllocationSiteSet.containsKey(d) ) {
+ buildAllocationSiteSet(d);
}
+ return mapDescriptorToAllocationSiteSet.get(d);
+ }
- private HashSet<Integer> getHeapRegionIDset( OwnershipGraph og,
- int paramIndex ) {
-
- assert og.paramIndex2id.containsKey( paramIndex );
- Integer idParam = og.paramIndex2id.get( paramIndex );
+ private void buildAllocationSiteSet(Descriptor d) {
+ HashSet<AllocationSite> s = new HashSet<AllocationSite>();
- HashSet<Integer> idSet = new HashSet<Integer>();
- idSet.add( idParam );
-
- return idSet;
+ FlatMethod fm;
+ if( d instanceof MethodDescriptor ) {
+ fm = state.getMethodFlat( (MethodDescriptor) d);
+ } else {
+ assert d instanceof TaskDescriptor;
+ fm = state.getMethodFlat( (TaskDescriptor) d);
}
- private HashSet<Integer> getHeapRegionIDset( AllocationSite alloc ) {
+ // visit every node in this FlatMethod's IR graph
+ // and make a set of the allocation sites from the
+ // FlatNew node's visited
+ HashSet<FlatNode> visited = new HashSet<FlatNode>();
+ HashSet<FlatNode> toVisit = new HashSet<FlatNode>();
+ toVisit.add(fm);
- HashSet<Integer> idSet = new HashSet<Integer>();
-
- for( int i = 0; i < alloc.getAllocationDepth(); ++i ) {
- Integer id = alloc.getIthOldest( i );
- idSet.add( id );
- }
-
- Integer idSummary = alloc.getSummary();
- idSet.add( idSummary );
+ while( !toVisit.isEmpty() ) {
+ FlatNode n = toVisit.iterator().next();
+
+ if( n instanceof FlatNew ) {
+ s.add(getAllocationSiteFromFlatNewPRIVATE( (FlatNew) n) );
+ }
- return idSet;
+ toVisit.remove(n);
+ visited.add(n);
+
+ for( int i = 0; i < n.numNext(); ++i ) {
+ FlatNode child = n.getNext(i);
+ if( !visited.contains(child) ) {
+ toVisit.add(child);
+ }
+ }
}
- private HashSet<Integer> getHeapRegionIDset( HashSet<AllocationSite> allocSet ) {
+ mapDescriptorToAllocationSiteSet.put(d, s);
+ }
- HashSet<Integer> idSet = new HashSet<Integer>();
-
- Iterator allocItr = allocSet.iterator();
- while( allocItr.hasNext() ) {
- AllocationSite alloc = (AllocationSite) allocItr.next();
- for( int i = 0; i < alloc.getAllocationDepth(); ++i ) {
- Integer id = alloc.getIthOldest( i );
- idSet.add( id );
- }
-
- Integer idSummary = alloc.getSummary();
- idSet.add( idSummary );
- }
+ private HashSet<AllocationSite>
+ getFlaggedAllocationSitesReachableFromTaskPRIVATE(TaskDescriptor td) {
- return idSet;
- }
+ HashSet<AllocationSite> asSetTotal = new HashSet<AllocationSite>();
+ HashSet<Descriptor> toVisit = new HashSet<Descriptor>();
+ HashSet<Descriptor> visited = new HashSet<Descriptor>();
- private boolean createsPotentialAliases( OwnershipGraph og,
- HashSet<Integer> idSetA,
- HashSet<Integer> idSetB ) {
- boolean potentialAlias = false;
+ toVisit.add(td);
- // first expand set B into the set of all heap region node ID's
- // reachable from the nodes in set B
- HashSet<Integer> idSetReachableFromB = og.getReachableSet( idSetB );
+ // traverse this task and all methods reachable from this task
+ while( !toVisit.isEmpty() ) {
+ Descriptor d = toVisit.iterator().next();
+ toVisit.remove(d);
+ visited.add(d);
- // then see if anything in A can reach a node in the set reachable
- // from B. If so, there is a potential alias.
- Iterator i = idSetA.iterator();
- while( i.hasNext() ) {
- Integer id = (Integer) i.next();
- if( og.canIdReachSet( id, idSetB ) ) {
- return true;
- }
+ HashSet<AllocationSite> asSet = getAllocationSiteSet(d);
+ Iterator asItr = asSet.iterator();
+ while( asItr.hasNext() ) {
+ AllocationSite as = (AllocationSite) asItr.next();
+ TypeDescriptor typed = as.getType();
+ if( typed != null ) {
+ ClassDescriptor cd = typed.getClassDesc();
+ if( cd != null && cd.hasFlags() ) {
+ asSetTotal.add(as);
+ }
}
+ }
- return false;
+ // enqueue callees of this method to be searched for
+ // allocation sites also
+ Set callees = callGraph.getCalleeSet(d);
+ if( callees != null ) {
+ Iterator methItr = callees.iterator();
+ while( methItr.hasNext() ) {
+ MethodDescriptor md = (MethodDescriptor) methItr.next();
+
+ if( !visited.contains(md) ) {
+ toVisit.add(md);
+ }
+ }
+ }
}
+
+
+ return asSetTotal;
+ }
}