Exemple #1
0
 RematSafetyInformation(TR::Compilation *comp) :
    dependentSymRefs(getTypedAllocator<TR::SparseBitVector>(comp->allocator())),
    argumentTreeTops(getTypedAllocator<TR::TreeTop*>(comp->allocator())),
    rematTreeTops(getTypedAllocator<TR::TreeTop*>(comp->allocator())),
    comp(comp)
    {
    }
Exemple #2
0
void
OMR::IlValue::storeToAuto()
   {
   if (_symRefThatCanBeUsedInOtherBlocks == NULL)
      {
      TR::Compilation *comp = TR::comp();

      // first use from another block, need to create symref and insert store tree where node  was computed
      TR::SymbolReference *symRef = comp->getSymRefTab()->createTemporary(_methodBuilder->methodSymbol(), _nodeThatComputesValue->getDataType());
      symRef->getSymbol()->setNotCollected();
      char *name = (char *) comp->trMemory()->allocateHeapMemory((2+10+1) * sizeof(char)); // 2 ("_T") + max 10 digits + trailing zero
      sprintf(name, "_T%u", symRef->getCPIndex());
      symRef->getSymbol()->getAutoSymbol()->setName(name);
      _methodBuilder->defineSymbol(name, symRef);

      // create store and its treetop
      TR::Node *storeNode = TR::Node::createStore(symRef, _nodeThatComputesValue);
      TR::TreeTop *prevTreeTop = _treeTopThatAnchorsValue->getPrevTreeTop();
      TR::TreeTop *newTree = TR::TreeTop::create(comp, storeNode);
      newTree->insertNewTreeTop(prevTreeTop, _treeTopThatAnchorsValue);

      _treeTopThatAnchorsValue->unlink(true);

      _treeTopThatAnchorsValue = newTree;
      _symRefThatCanBeUsedInOtherBlocks = symRef;
      }
   }
Exemple #3
0
void TR::ExternalRelocation::apply(TR::CodeGenerator *codeGen)
   {
   TR::Compilation *comp = codeGen->comp();
   AOTcgDiag1(comp, "TR::ExternalRelocation::apply updateLocation=" POINTER_PRINTF_FORMAT " \n", getUpdateLocation());
   uint8_t * relocatableMethodCodeStart = (uint8_t *)comp->getRelocatableMethodCodeStart();
   getRelocationRecord()->addRelocationEntry((uint32_t)(getUpdateLocation() - relocatableMethodCodeStart));
   }
Exemple #4
0
uint8_t TR::ExternalOrderedPair32BitRelocation::collectModifier()
   {
   TR::Compilation *comp = TR::comp();
   uint8_t * relocatableMethodCodeStart = (uint8_t *)comp->getRelocatableMethodCodeStart();
   uint8_t * updateLocation;
   uint8_t * updateLocation2;
   TR_ExternalRelocationTargetKind kind = getTargetKind();

   if (TR::Compiler->target.cpu.isPower() &&
          (kind == TR_ArrayCopyHelper || kind == TR_ArrayCopyToc || kind == TR_RamMethod || kind == TR_GlobalValue || kind == TR_BodyInfoAddressLoad || kind == TR_DataAddress || kind == TR_DebugCounter))
      {
      TR::Instruction *instr = (TR::Instruction *)getUpdateLocation();
      TR::Instruction *instr2 = (TR::Instruction *)getLocation2();
      updateLocation = instr->getBinaryEncoding();
      updateLocation2 = instr2->getBinaryEncoding();
      }
   else
      {
      updateLocation = getUpdateLocation();
      updateLocation2 = getLocation2();
      }

   int32_t iLoc = updateLocation - relocatableMethodCodeStart;
   int32_t iLoc2 = updateLocation2 - relocatableMethodCodeStart;
   AOTcgDiag0(comp, "TR::ExternalOrderedPair32BitRelocation::collectModifier\n");
   if ( (iLoc < MIN_SHORT_OFFSET  || iLoc > MAX_SHORT_OFFSET ) || (iLoc2 < MIN_SHORT_OFFSET || iLoc2 > MAX_SHORT_OFFSET ) )
      return RELOCATION_TYPE_WIDE_OFFSET | RELOCATION_TYPE_ORDERED_PAIR;

   return RELOCATION_TYPE_ORDERED_PAIR;
   }
Exemple #5
0
TR_RuntimeHelper TR::S390CallSnippet::getInterpretedDispatchHelper(
   TR::SymbolReference *methodSymRef,
   TR::DataType        type)
   {
   TR::Compilation *comp = cg()->comp();
   TR::MethodSymbol * methodSymbol = methodSymRef->getSymbol()->castToMethodSymbol();
   bool isJitInduceOSRCall = false;
   if (methodSymbol->isHelper() &&
       methodSymRef->isOSRInductionHelper())
      {
      isJitInduceOSRCall = true;
      }

   if (methodSymRef->isUnresolved() || comp->compileRelocatableCode())
      {
      TR_ASSERT(!isJitInduceOSRCall || !comp->compileRelocatableCode(), "calling jitInduceOSR is not supported yet under AOT\n");
      if (methodSymbol->isSpecial())
         return TR_S390interpreterUnresolvedSpecialGlue;
      else if (methodSymbol->isStatic())
         return TR_S390interpreterUnresolvedStaticGlue;
      else
         return TR_S390interpreterUnresolvedDirectVirtualGlue;
      }
   else if (isJitInduceOSRCall)
      return (TR_RuntimeHelper) methodSymRef->getReferenceNumber();
   else
      return getHelper(methodSymbol, type, cg());
   }
Exemple #6
0
void
OMR::CodeGenPhase::performInliningReportPhase(TR::CodeGenerator * cg, TR::CodeGenPhase * phase)
   {
   TR::Compilation * comp = cg->comp();
   if (comp->getOptions()->insertDebuggingCounters()>1)
   TR_DebuggingCounters::inliningReportForMethod(comp);
   }
Exemple #7
0
void
TR::PPCImmInstruction::addMetaDataForCodeAddress(uint8_t *cursor)
   {

   if (needsAOTRelocation())
      {
         switch(getReloKind())
            {
            case TR_AbsoluteHelperAddress:
               cg()->addExternalRelocation(new (cg()->trHeapMemory()) TR::ExternalRelocation(cursor, (uint8_t *)getSymbolReference(), TR_AbsoluteHelperAddress, cg()), __FILE__, __LINE__, getNode());
               break;
            case TR_RamMethod:
               if (comp()->getOption(TR_UseSymbolValidationManager))
                  {
                  cg()->addExternalRelocation(
                     new (comp()->trHeapMemory()) TR::ExternalRelocation(
                        cursor,
                        (uint8_t *)comp()->getJittedMethodSymbol()->getResolvedMethod()->resolvedMethodAddress(),
                        (uint8_t *)TR::SymbolType::typeMethod,
                        TR_SymbolFromManager,
                        cg()),
                     __FILE__,
                     __LINE__,
                     getNode());
                  }
               else
                  {
                  cg()->addExternalRelocation(new (cg()->trHeapMemory()) TR::ExternalRelocation(cursor, NULL, TR_RamMethod, cg()), __FILE__, __LINE__, getNode());
                  }
               break;
            case TR_BodyInfoAddress:
               cg()->addExternalRelocation(new (cg()->trHeapMemory()) TR::ExternalRelocation(cursor, 0, TR_BodyInfoAddress, cg()), __FILE__, __LINE__, getNode());
               break;
            default:
               TR_ASSERT(false, "Unsupported AOT relocation type specified.");
            }
      }

   TR::Compilation *comp = cg()->comp();
   if (std::find(comp->getStaticPICSites()->begin(), comp->getStaticPICSites()->end(), this) != comp->getStaticPICSites()->end())
      {
      // none-HCR: low-tag to invalidate -- BE or LE is relevant
      //
      void *valueToHash = *(void**)(cursor - (TR::Compiler->target.is64Bit()?4:0));
      void *addressToPatch = TR::Compiler->target.is64Bit()?
         (TR::Compiler->target.cpu.isBigEndian()?cursor:(cursor-4)) : cursor;
      cg()->jitAddPicToPatchOnClassUnload(valueToHash, addressToPatch);
      }

   if (std::find(comp->getStaticHCRPICSites()->begin(), comp->getStaticHCRPICSites()->end(), this) != comp->getStaticHCRPICSites()->end())
      {
      // HCR: whole pointer replacement.
      //
      void **locationToPatch = (void**)(cursor - (TR::Compiler->target.is64Bit()?4:0));
      cg()->jitAddPicToPatchOnClassRedefinition(*locationToPatch, locationToPatch);
      cg()->addExternalRelocation(new (cg()->trHeapMemory()) TR::ExternalRelocation((uint8_t *)locationToPatch, (uint8_t *)*locationToPatch, TR_HCR, cg()), __FILE__,__LINE__, getNode());
      }

   }
Exemple #8
0
void
OMR::CodeGenPhase::performRemoveUnusedLocalsPhase(TR::CodeGenerator * cg, TR::CodeGenPhase * phase)
   {
   TR::Compilation *comp = cg->comp();
   phase->reportPhase(RemoveUnusedLocalsPhase);
   TR::LexicalMemProfiler mp(phase->getName(), comp->phaseMemProfiler());
   LexicalTimer pt(phase->getName(), comp->phaseTimer());
   cg->removeUnusedLocals();
   }
Exemple #9
0
void
OMR::CodeGenPhase::performRegisterAssigningPhase(TR::CodeGenerator * cg, TR::CodeGenPhase * phase)
   {
   TR::Compilation* comp = cg->comp();
   phase->reportPhase(RegisterAssigningPhase);

   if (cg->getDebug())
      cg->getDebug()->roundAddressEnumerationCounters();

     {
      TR::LexicalMemProfiler mp("RA", comp->phaseMemProfiler());
      LexicalTimer pt("RA", comp->phaseTimer());

      TR_RegisterKinds colourableKindsToAssign;
      TR_RegisterKinds nonColourableKindsToAssign = cg->prepareRegistersForAssignment();

      cg->jettisonAllSpills(); // Spill temps used before now may lead to conflicts if also used by register assignment

      // Do local register assignment for non-colourable registers.
      //
      if(cg->getTraceRAOption(TR_TraceRAListing))
         if(cg->getDebug()) cg->getDebug()->dumpMethodInstrs(comp->getOutFile(),"Before Local RA",false);

      cg->doRegisterAssignment(nonColourableKindsToAssign);

      if (comp->compilationShouldBeInterrupted(AFTER_REGISTER_ASSIGNMENT_CONTEXT))
         {
         comp->failCompilation<TR::CompilationInterrupted>("interrupted after RA");
         }
      }

   if (comp->getOption(TR_TraceCG) || comp->getOptions()->getTraceCGOption(TR_TraceCGPostRegisterAssignment))
      comp->getDebug()->dumpMethodInstrs(comp->getOutFile(), "Post Register Assignment Instructions", false, true);
   }
Exemple #10
0
void
OMR::CodeGenPhase::performLowerTreesPhase(TR::CodeGenerator * cg, TR::CodeGenPhase * phase)
   {
   TR::Compilation * comp = cg->comp();
   phase->reportPhase(LowerTreesPhase);

   cg->lowerTrees();

   if (comp->getOption(TR_TraceCG))
      comp->dumpMethodTrees("Post Lower Trees");
   }
Exemple #11
0
bool
OMR::SymbolReference::storeCanBeRemoved()
   {
   TR::Compilation *comp = TR::comp();
   TR::Symbol * s = self()->getSymbol();

   return !s->isVolatile() &&
     (((s->getDataType() != TR::Double) && (s->getDataType() != TR::Float)) ||
           comp->cg()->getSupportsJavaFloatSemantics() ||
           (self()->isTemporary(comp) && !s->behaveLikeNonTemp()));
   }
Exemple #12
0
bool
OMR::SymbolReference::sharesSymbol(bool includingGCSafePoint)
   {
   TR::Compilation * c = TR::comp();
   if (self()->reallySharesSymbol(c))
      return true;

   // At this point, we'd like to call getUseDefAliases(c, false) and return
   // true iff that is non-NULL.  However, doing so caused floatSanity
   // (specifically CompactNullChecks) to consume immense amounts (1GB+) of
   // memory and run for a long, long time (half an hour or more in some
   // cases), so we need to copy some of that logic in here as a short-circuit.
   //
   // !!! NOTE !!!
   // THERE IS A COPY OF THIS LOGIC IN getUseDefAliases
   //
   int32_t kind = _symbol->getKind();
   TR::SymbolReferenceTable * symRefTab = c->getSymRefTab();
   switch (kind)
      {
      case TR::Symbol::IsShadow:
      case TR::Symbol::IsStatic:
         {
         // For unresolved constant dynamic, we need to invoke a Java bootstrap method,
         // which can have arbitrary side effects, so the aliasing should be conservative here.
         // isConstObjectRef now returns true for condy, so we add an explicit condition,
         // more like a short-circuit, to say if we are unresolved and not isConstObjectRef
         // (this is the same as before), or if we are unresolved and condy
         // (this is the extra condition added), we would return conservative aliases.
         if ((self()->isUnresolved() && (_symbol->isConstantDynamic() || !_symbol->isConstObjectRef())) ||
	       _symbol->isVolatile() || self()->isLiteralPoolAddress() ||
               self()->isFromLiteralPool() || _symbol->isUnsafeShadowSymbol() ||
               (_symbol->isArrayShadowSymbol() && c->getMethodSymbol()->hasVeryRefinedAliasSets()))
            {
            // getUseDefAliases might not return NULL
            }
         else if (!symRefTab->aliasBuilder.mutableGenericIntShadowHasBeenCreated())
            {
            // getUseDefAliases must return NULL
            return false;
            }
         else if (kind == TR::Symbol::IsStatic && !symRefTab->aliasBuilder.litPoolGenericIntShadowHasBeenCreated())
            {
            // getUseDefAliases must return NULL
            return false;
            }
         break;
         }
      }

   return !self()->getUseDefAliases(false, includingGCSafePoint).isZero(c);
   }
Exemple #13
0
OMR::LabelSymbol::LabelSymbol(TR::CodeGenerator *codeGen, TR::Block *labb) :
   TR::Symbol(),
   _instruction(NULL),
   _codeLocation(NULL),
   _estimatedCodeLocation(0),
   _snippet(NULL)
   {
   self()->setIsLabel();

   TR::Compilation *comp = TR::comp();
   if (comp && comp->getDebug())
      comp->getDebug()->newLabelSymbol(self());
   }
Exemple #14
0
OMR::LabelSymbol::LabelSymbol() :
   TR::Symbol(),
   _instruction(NULL),
   _codeLocation(NULL),
   _estimatedCodeLocation(0),
   _snippet(NULL),
   _directlyTargeted(false)
   {
   self()->setIsLabel();

   TR::Compilation *comp = TR::comp();
   if (comp && comp->getDebug())
      comp->getDebug()->newLabelSymbol(self());
   }
Exemple #15
0
void
TR::PPCTrg1Src1ImmInstruction::addMetaDataForCodeAddress(uint8_t *cursor)
   {
   TR::Compilation *comp = cg()->comp();

   if (std::find(comp->getStaticPICSites()->begin(), comp->getStaticPICSites()->end(), this) != comp->getStaticPICSites()->end())
      {
      cg()->jitAddPicToPatchOnClassUnload((void *)(getSourceImmPtr()), (void *)cursor);
      }
   if (std::find(comp->getStaticMethodPICSites()->begin(), comp->getStaticMethodPICSites()->end(), this) != comp->getStaticMethodPICSites()->end())
      {
      cg()->jitAddPicToPatchOnClassUnload((void *) (cg()->fe()->createResolvedMethod(cg()->trMemory(), (TR_OpaqueMethodBlock *) (getSourceImmPtr()), comp->getCurrentMethod())->classOfMethod()), (void *)cursor);
      }
   }
Exemple #16
0
uint8_t TR::ExternalRelocation::collectModifier()
   {
   TR::Compilation *comp = TR::comp();
   uint8_t * relocatableMethodCodeStart = (uint8_t *)comp->getRelocatableMethodCodeStart();
   uint8_t * updateLocation = getUpdateLocation();

   int32_t distanceFromStartOfBuffer = updateLocation - relocatableMethodCodeStart;
   int32_t distanceFromStartOfMethod = updateLocation - comp->cg()->getCodeStart();
   AOTcgDiag2(comp, "TR::ExternalRelocation::collectModifier distance from start of buffer=%x, from start of method=%x\n", distanceFromStartOfBuffer, distanceFromStartOfMethod);

   if (distanceFromStartOfBuffer < MIN_SHORT_OFFSET || distanceFromStartOfBuffer > MAX_SHORT_OFFSET)
      return RELOCATION_TYPE_WIDE_OFFSET;

   return 0;
   }
Exemple #17
0
/**
 * make these two array shadows independent of each other, but still aliased to
 * all other array shadows
 */
void
OMR::SymbolReference::makeIndependent(TR::SymbolReferenceTable *symRefTab,
                                      TR::SymbolReference *symRef)
   {
   TR::Compilation *comp = symRefTab->comp();
   TR_ASSERT(self()->getSymbol()->isArrayShadowSymbol(),"symref #%d is not an array shadow\n",self()->getReferenceNumber());
   TR_ASSERT(symRef->getSymbol()->isArrayShadowSymbol(),"symref #%d is not an array shadow\n",symRef->getReferenceNumber());
   if(NULL == self()->getIndependentSymRefs())
      self()->setIndependentSymRefs(new(comp->trHeapMemory()) TR_BitVector(symRefTab->getNumSymRefs(),comp->trMemory(),heapAlloc,growable));

   if(NULL == symRef->getIndependentSymRefs())
      symRef->setIndependentSymRefs(new(comp->trHeapMemory()) TR_BitVector(symRefTab->getNumSymRefs(),comp->trMemory(),heapAlloc,growable));

   self()->getIndependentSymRefs()->set(symRef->getReferenceNumber());
   symRef->getIndependentSymRefs()->set(self()->getReferenceNumber());

   }
Exemple #18
0
void
TR::PPCTrg1ImmInstruction::addMetaDataForCodeAddress(uint8_t *cursor)
   {
   TR::Compilation *comp = cg()->comp();

   if (std::find(comp->getStaticPICSites()->begin(), comp->getStaticPICSites()->end(), this) != comp->getStaticPICSites()->end())
      {
      TR::Node *node = getNode();
      cg()->jitAddPicToPatchOnClassUnload((void *)(TR::Compiler->target.is64Bit()?node->getLongInt():node->getInt()), (void *)cursor);
      }

   if (std::find(comp->getStaticMethodPICSites()->begin(), comp->getStaticMethodPICSites()->end(), this) != comp->getStaticMethodPICSites()->end())
      {
      TR::Node *node = getNode();
      cg()->jitAddPicToPatchOnClassUnload((void *) (cg()->fe()->createResolvedMethod(cg()->trMemory(), (TR_OpaqueMethodBlock *) (TR::Compiler->target.is64Bit()?node->getLongInt():node->getInt()), comp->getCurrentMethod())->classOfMethod()), (void *)cursor);
      }
   }
Exemple #19
0
void
OMR::CodeGenPhase::performBinaryEncodingPhase(TR::CodeGenerator * cg, TR::CodeGenPhase * phase)
   {
   TR::Compilation * comp = cg->comp();
   phase->reportPhase(BinaryEncodingPhase);

   if (cg->getDebug())
      cg->getDebug()->roundAddressEnumerationCounters();

   TR::LexicalMemProfiler mp(phase->getName(), comp->phaseMemProfiler());
   LexicalTimer pt(phase->getName(), comp->phaseTimer());

   cg->doBinaryEncoding();

   if (debug("verifyFinalNodeReferenceCounts"))
      {
      if (cg->getDebug())
         cg->getDebug()->verifyFinalNodeReferenceCounts(comp->getMethodSymbol());
      }
   }
   /// called to identify the branches and their targets in the method
   ///  causes the _blocks array to be filled in with the basic blocks of the method
   void findAndMarkBranchTargets()
      {
      TR::Compilation *comp = this->comp();
      if (debug("branchTargets"))
         diagnostic("findAndMarkBranchTargets for %s\n", comp->signature());

      aboutToFindBranchTargets();

      for (ByteCode bc = this->first(); bc != BCunknown; bc = this->next())
         {
         if (_printByteCodes)
            this->printByteCode();

         int32_t i = this->bcIndex();
         if (this->isBranch())
            markTarget(i, this->branchDestination(i) - i);
         markAnySpecialBranchTargets(bc);
         }
      finishedFindingBranchTargets();
      }
Exemple #21
0
void TR::ExternalOrderedPair32BitRelocation::apply(TR::CodeGenerator *codeGen)
   {
   TR::Compilation *comp = codeGen->comp();
   AOTcgDiag0(comp, "TR::ExternalOrderedPair32BitRelocation::apply\n");

   TR::IteratedExternalRelocation *rec = getRelocationRecord();
   uint8_t *codeStart = (uint8_t *)comp->getRelocatableMethodCodeStart();
   TR_ExternalRelocationTargetKind kind = getRelocationRecord()->getTargetKind();
   if (TR::Compiler->target.cpu.isPower() &&
      (kind == TR_ArrayCopyHelper || kind == TR_ArrayCopyToc || kind == TR_RamMethodSequence || kind == TR_GlobalValue || kind == TR_BodyInfoAddressLoad || kind == TR_DataAddress || kind == TR_DebugCounter))
      {
      TR::Instruction *instr = (TR::Instruction *)getUpdateLocation();
      TR::Instruction *instr2 = (TR::Instruction *)getLocation2();
      rec->addRelocationEntry((uint32_t)(instr->getBinaryEncoding() - codeStart));
      rec->addRelocationEntry((uint32_t)(instr2->getBinaryEncoding() - codeStart));
      }
   else
      {
      rec->addRelocationEntry(getUpdateLocation() - codeStart);
      rec->addRelocationEntry(getLocation2() - codeStart);
      }
   }
Exemple #22
0
void
TestCompiler::FrontEnd::generateBinaryEncodingPrologue(
      TR_BinaryEncodingData *beData,
      TR::CodeGenerator *cg)
   {
   TR::Compilation* comp = cg->comp();
   TR_S390BinaryEncodingData *data = (TR_S390BinaryEncodingData *)beData;

   data->cursorInstruction = comp->getFirstInstruction();
   data->estimate = 0;
   data->preProcInstruction = data->cursorInstruction;
   data->jitTojitStart = data->cursorInstruction;
   data->cursorInstruction = NULL;

   TR::Instruction * preLoadArgs, * endLoadArgs;
   preLoadArgs = data->preProcInstruction;
   endLoadArgs = preLoadArgs;

   TR::Instruction * oldFirstInstruction = data->cursorInstruction;

   data->cursorInstruction = comp->getFirstInstruction();

   static char *disableAlignJITEP = feGetEnv("TR_DisableAlignJITEP");

   // Padding for JIT Entry Point
   if (!disableAlignJITEP)
      {
      data->estimate += 256;
      }

   while (data->cursorInstruction && data->cursorInstruction->getOpCodeValue() != TR::InstOpCode::PROC)
      {
      data->estimate = data->cursorInstruction->estimateBinaryLength(data->estimate);
      data->cursorInstruction = data->cursorInstruction->getNext();
      }

   cg->getLinkage()->createPrologue(data->cursorInstruction);
   //cg->getLinkage()->analyzePrologue();
   }
Exemple #23
0
void
OMR::CodeGenPhase::performMapStackPhase(TR::CodeGenerator * cg, TR::CodeGenPhase * phase)
   {
   TR::Compilation* comp = cg->comp();
   cg->remapGCIndicesInInternalPtrFormat();
     {
     TR::LexicalMemProfiler mp("Stackmap", comp->phaseMemProfiler());
     LexicalTimer pt("Stackmap", comp->phaseTimer());

     cg->getLinkage()->mapStack(comp->getJittedMethodSymbol());

     if (comp->getOption(TR_TraceCG) || comp->getOptions()->getTraceCGOption(TR_TraceEarlyStackMap))
        comp->getDebug()->dumpMethodInstrs(comp->getOutFile(), "Post Stack Map", false);
     }
   cg->setMappingAutomatics();

   }
Exemple #24
0
void
OMR::CodeGenPhase::performUncommonCallConstNodesPhase(TR::CodeGenerator * cg, TR::CodeGenPhase * phase)
   {
   TR::Compilation* comp = cg->comp();

   if(comp->getOption(TR_DisableCallConstUncommoning))
      {
      traceMsg(comp, "Skipping Uncommon Call Constant Node phase\n");
      return;
      }

   phase->reportPhase(UncommonCallConstNodesPhase);

   if (comp->getOption(TR_TraceCG) || comp->getOption(TR_TraceTrees))
      comp->dumpMethodTrees("Pre Uncommon Call Constant Node Trees");

   TR::LexicalMemProfiler mp(phase->getName(), comp->phaseMemProfiler());
   LexicalTimer pt(phase->getName(), comp->phaseTimer());

   cg->uncommonCallConstNodes();

   if (comp->getOption(TR_TraceCG) || comp->getOption(TR_TraceTrees))
      comp->dumpMethodTrees("Post Uncommon Call Constant Node Trees");
  }
Exemple #25
0
TR::Register *OMR::X86::AMD64::TreeEvaluator::i2lEvaluator(TR::Node *node, TR::CodeGenerator *cg)
   {
   TR::Compilation *comp = cg->comp();
   if (node->getFirstChild()->getOpCode().isLoadConst())
      {
      TR::Register *targetRegister = cg->allocateRegister();

      generateRegImmInstruction(MOV8RegImm4, node, targetRegister, node->getFirstChild()->getInt(), cg);

      node->setRegister(targetRegister);
      cg->decReferenceCount(node->getFirstChild());

      return targetRegister;
      }
   else
      {
      // In theory, because iRegStore has chosen to disregard needsSignExtension,
      // we must disregard skipSignExtension here for correctness.
      //
      // However, in fact, it is actually safe to obey skipSignExtension so
      // long as the optimizer only uses it on nodes known to be non-negative
      // when the i2l occurs.  We do already have isNonNegative for that
      // purpose, but it may not always be set by the optimizer if a node known
      // to be non-negative at one point in a block is commoned up above the
      // BNDCHK or branch that determines the node's non-negativity.  The
      // codegen does set the flag during tree evaluation, but the
      // skipSignExtension flag is set by the optimizer with more global
      // knowledge than the tree evaluator, so we will trust it.
      //
      TR_X86OpCodes regMemOpCode,regRegOpCode;
      if(   node->isNonNegative()
         || (node->skipSignExtension() && performTransformation(comp, "TREE EVALUATION: skipping sign extension on node %s despite lack of isNonNegative\n", comp->getDebug()->getName(node))))
         {
         // We prefer these plain (zero-extending) opcodes because the analyser can often eliminate them
         //
         regMemOpCode = L4RegMem;
         regRegOpCode = MOVZXReg8Reg4;
         }
      else
         {
         regMemOpCode = MOVSXReg8Mem4;
         regRegOpCode = MOVSXReg8Reg4;
         }
      return TR::TreeEvaluator::conversionAnalyser(node, regMemOpCode, regRegOpCode, cg);
      }
   }
Exemple #26
0
LexicalXmlTag::LexicalXmlTag(TR::CodeGenerator * cg): cg(cg)
   {
   TR::Compilation *comp = cg->comp();
   if (comp->getOption(TR_TraceOptDetails) || comp->getOption(TR_TraceCG))
      {
      const char *hotnessString = comp->getHotnessName(comp->getMethodHotness());
      traceMsg(comp, "<codegen\n"
              "\tmethod=\"%s\"\n"
               "\thotness=\"%s\">\n",
               comp->signature(), hotnessString);
      }
   }
Exemple #27
0
void
OMR::CodeGenPhase::performPeepholePhase(TR::CodeGenerator * cg, TR::CodeGenPhase * phase)
   {
   TR::Compilation * comp = cg->comp();
   phase->reportPhase(PeepholePhase);

   TR::LexicalMemProfiler mp(phase->getName(), comp->phaseMemProfiler());
   LexicalTimer pt(phase->getName(), comp->phaseTimer());

   cg->doPeephole();

   if (comp->getOption(TR_TraceCG))
      comp->getDebug()->dumpMethodInstrs(comp->getOutFile(), "Post Peephole Instructions", false);
   }
void TR_PPCRegisterDependencyGroup::assignRegisters(TR::Instruction   *currentInstruction,
                                                    TR_RegisterKinds  kindToBeAssigned,
                                                    uint32_t          numberOfRegisters,
                                                    TR::CodeGenerator *cg)
   {
   // *this    swipeable for debugging purposes
   TR::Machine *machine = cg->machine();
   TR::Register   *virtReg;
   TR::RealRegister::RegNum dependentRegNum;
   TR::RealRegister *dependentRealReg, *assignedRegister, *realReg;
   int i, j;
   TR::Compilation *comp = cg->comp();

   int num_gprs = 0;
   int num_fprs = 0;
   int num_vrfs = 0;

   // Use to do lookups using real register numbers
   TR_PPCRegisterDependencyMap map(_dependencies, numberOfRegisters);

   if (!comp->getOption(TR_DisableOOL))
      {
      for (i = 0; i< numberOfRegisters; i++)
         {
         virtReg = _dependencies[i].getRegister();
         dependentRegNum = _dependencies[i].getRealRegister();
         if (dependentRegNum == TR::RealRegister::SpilledReg)
            {
            TR_ASSERT(virtReg->getBackingStorage(),"should have a backing store if dependentRegNum == spillRegIndex()\n");
            if (virtReg->getAssignedRealRegister())
               {
               // this happens when the register was first spilled in main line path then was reverse spilled
               // and assigned to a real register in OOL path. We protected the backing store when doing
               // the reverse spill so we could re-spill to the same slot now
               traceMsg (comp,"\nOOL: Found register spilled in main line and re-assigned inside OOL");
               TR::Node *currentNode = currentInstruction->getNode();
               TR::RealRegister *assignedReg    = toRealRegister(virtReg->getAssignedRegister());
               TR::MemoryReference *tempMR = new (cg->trHeapMemory()) TR::MemoryReference(currentNode, (TR::SymbolReference*)virtReg->getBackingStorage()->getSymbolReference(), sizeof(uintptr_t), cg);
               TR::InstOpCode::Mnemonic opCode;
               TR_RegisterKinds rk = virtReg->getKind();
               switch (rk)
                  {
                  case TR_GPR:
                     opCode =TR::InstOpCode::Op_load;
                     break;
                  case TR_FPR:
                     opCode = virtReg->isSinglePrecision() ? TR::InstOpCode::lfs : TR::InstOpCode::lfd;
                     break;
                  default:
                     TR_ASSERT(0, "\nRegister kind not supported in OOL spill\n");
                     break;
                  }

               TR::Instruction *inst = generateTrg1MemInstruction(cg, opCode, currentNode, assignedReg, tempMR, currentInstruction);

               assignedReg->setAssignedRegister(NULL);
               virtReg->setAssignedRegister(NULL);
               assignedReg->setState(TR::RealRegister::Free);
               if (comp->getDebug())
                  cg->traceRegisterAssignment("Generate reload of virt %s due to spillRegIndex dep at inst %p\n",comp->getDebug()->getName(virtReg),currentInstruction);
               cg->traceRAInstruction(inst);
               }

            if (!(std::find(cg->getSpilledRegisterList()->begin(), cg->getSpilledRegisterList()->end(), virtReg) != cg->getSpilledRegisterList()->end()))
               cg->getSpilledRegisterList()->push_front(virtReg);
            }
         // we also need to free up all locked backing storage if we are exiting the OOL during backwards RA assignment
         else if (currentInstruction->isLabel() && virtReg->getAssignedRealRegister())
            {
            TR::PPCLabelInstruction *labelInstr = (TR::PPCLabelInstruction *)currentInstruction;
            TR_BackingStore * location = virtReg->getBackingStorage();
            TR_RegisterKinds rk = virtReg->getKind();
            int32_t dataSize;
            if (labelInstr->getLabelSymbol()->isStartOfColdInstructionStream() && location)
               {
               traceMsg (comp,"\nOOL: Releasing backing storage (%p)\n", location);
               if (rk == TR_GPR)
                  dataSize = TR::Compiler->om.sizeofReferenceAddress();
               else
                  dataSize = 8;
               location->setMaxSpillDepth(0);
               cg->freeSpill(location,dataSize,0);
               virtReg->setBackingStorage(NULL);
               }
            }
         }
      }

   for (i = 0; i < numberOfRegisters; i++)
      {
      map.addDependency(_dependencies[i], i);

      virtReg = _dependencies[i].getRegister();
      dependentRegNum = _dependencies[i].getRealRegister();

      if (dependentRegNum != TR::RealRegister::SpilledReg)
         {
         if (virtReg->getKind() == TR_GPR)
            num_gprs++;
         else if (virtReg->getKind() == TR_FPR)
            num_fprs++;
         else if (virtReg->getKind() == TR_VRF)
            num_vrfs++;
         }
      }

#ifdef DEBUG
   int locked_gprs = 0;
   int locked_fprs = 0;
   int locked_vrfs = 0;

   // count up how many registers are locked for each type
   for(i = TR::RealRegister::FirstGPR; i <= TR::RealRegister::LastGPR; i++)
      {
        realReg = machine->getPPCRealRegister((TR::RealRegister::RegNum)i);
        if (realReg->getState() == TR::RealRegister::Locked)
           locked_gprs++;
      }
   for(i = TR::RealRegister::FirstFPR; i <= TR::RealRegister::LastFPR; i++)
      {
        realReg = machine->getPPCRealRegister((TR::RealRegister::RegNum)i);
        if (realReg->getState() == TR::RealRegister::Locked)
           locked_fprs++;
      }
   for(i = TR::RealRegister::FirstVRF; i <= TR::RealRegister::LastVRF; i++)
      {
        realReg = machine->getPPCRealRegister((TR::RealRegister::RegNum)i);
        if (realReg->getState() == TR::RealRegister::Locked)
           locked_vrfs++;
      }
   TR_ASSERT( locked_gprs == machine->getNumberOfLockedRegisters(TR_GPR),"Inconsistent number of locked GPRs");
   TR_ASSERT( locked_fprs == machine->getNumberOfLockedRegisters(TR_FPR),"Inconsistent number of locked FPRs");
   TR_ASSERT( locked_vrfs == machine->getNumberOfLockedRegisters(TR_VRF), "Inconsistent number of locked VRFs");
#endif

   // To handle circular dependencies, we block a real register if (1) it is already assigned to a correct
   // virtual register and (2) if it is assigned to one register in the list but is required by another.
   // However, if all available registers are requested, we do not block in case (2) to avoid all registers
   // being blocked.

   bool block_gprs = true;
   bool block_fprs = true;
   bool block_vrfs = true;

   TR_ASSERT(num_gprs <= (TR::RealRegister::LastGPR - TR::RealRegister::FirstGPR + 1 - machine->getNumberOfLockedRegisters(TR_GPR)), "Too many GPR dependencies, unable to assign" );
   TR_ASSERT(num_fprs <= (TR::RealRegister::LastFPR - TR::RealRegister::FirstFPR + 1 - machine->getNumberOfLockedRegisters(TR_FPR)), "Too many FPR dependencies, unable to assign" );
   TR_ASSERT(num_vrfs <= (TR::RealRegister::LastVRF - TR::RealRegister::FirstVRF + 1 - machine->getNumberOfLockedRegisters(TR_VRF)), "Too many VRF dependencies, unable to assign" );

   if (num_gprs == (TR::RealRegister::LastGPR - TR::RealRegister::FirstGPR + 1 - machine->getNumberOfLockedRegisters(TR_GPR)))
        block_gprs = false;
   if (num_fprs == (TR::RealRegister::LastFPR - TR::RealRegister::FirstFPR + 1 - machine->getNumberOfLockedRegisters(TR_FPR)))
        block_fprs = false;
   if (num_vrfs == (TR::RealRegister::LastVRF - TR::RealRegister::FirstVRF + 1 - machine->getNumberOfLockedRegisters(TR_VRF)))
        block_vrfs = false;

   for (i = 0; i < numberOfRegisters; i++)
      {
      virtReg = _dependencies[i].getRegister();

      if (virtReg->getAssignedRealRegister()!=NULL)
         {
         if (_dependencies[i].getRealRegister() == TR::RealRegister::NoReg)
            {
            virtReg->block();
            }
         else
            {
            TR::RealRegister::RegNum assignedRegNum;
            assignedRegNum = toRealRegister(virtReg->getAssignedRealRegister())->getRegisterNumber();

            // always block if required register and assigned register match;
            // block if assigned register is required by other dependency but only if
            // any spare registers are left to avoid blocking all existing registers
            if (_dependencies[i].getRealRegister() == assignedRegNum ||
                (map.getDependencyWithTarget(assignedRegNum) &&
                 ((virtReg->getKind() != TR_GPR || block_gprs) &&
                  (virtReg->getKind() != TR_FPR || block_fprs) &&
                  (virtReg->getKind() != TR_VRF || block_vrfs))))
               {
               virtReg->block();
               }
            }
         }
      }

   // Assign all virtual regs that depend on a specific real reg that is free
   for (i = 0; i < numberOfRegisters; i++)
      {
      virtReg = _dependencies[i].getRegister();
      dependentRegNum = _dependencies[i].getRealRegister();
      dependentRealReg = machine->getPPCRealRegister(dependentRegNum);

      if (dependentRegNum != TR::RealRegister::NoReg &&
          dependentRegNum != TR::RealRegister::SpilledReg &&
          dependentRealReg->getState() == TR::RealRegister::Free)
         {
         assignFreeRegisters(currentInstruction, &_dependencies[i], map, cg);
         }
      }

   // Assign all virtual regs that depend on a specfic real reg that is not free
   for (i = 0; i < numberOfRegisters; i++)
      {
      virtReg     = _dependencies[i].getRegister();
      assignedRegister = NULL;
      if (virtReg->getAssignedRealRegister() != NULL)
         {
         assignedRegister = toRealRegister(virtReg->getAssignedRealRegister());
         }
      dependentRegNum = _dependencies[i].getRealRegister();
      dependentRealReg = machine->getPPCRealRegister(dependentRegNum);
      if (dependentRegNum != TR::RealRegister::NoReg &&
          dependentRegNum != TR::RealRegister::SpilledReg &&
          dependentRealReg != assignedRegister)
         {
         bool depsBlocked = false;
         switch (_dependencies[i].getRegister()->getKind())
            {
            case TR_GPR:
               depsBlocked = block_gprs;
               break;
            case TR_FPR:
               depsBlocked = block_fprs;
               break;
            case TR_VRF:
               depsBlocked = block_vrfs;
               break;
            }
         assignContendedRegisters(currentInstruction, &_dependencies[i], map, depsBlocked, cg);
         }
      }

   // Assign all virtual regs that depend on NoReg but exclude gr0
   for (i=0; i<numberOfRegisters; i++)
      {
      if (_dependencies[i].getRealRegister() == TR::RealRegister::NoReg && _dependencies[i].getExcludeGPR0())
         {
         TR::RealRegister *realOne;

         virtReg     = _dependencies[i].getRegister();
         realOne     = virtReg->getAssignedRealRegister();
         if (realOne!=NULL && toRealRegister(realOne)->getRegisterNumber()==TR::RealRegister::gr0)
            {
            if ((assignedRegister = machine->findBestFreeRegister(currentInstruction, virtReg->getKind(), true, false, virtReg)) == NULL)
               {
               assignedRegister = machine->freeBestRegister(currentInstruction, virtReg, NULL, true);
               }
            machine->coerceRegisterAssignment(currentInstruction, virtReg, assignedRegister->getRegisterNumber());
            }
         else if (realOne == NULL)
            {
            machine->assignOneRegister(currentInstruction, virtReg, true);
            }
         virtReg->block();
         }
      }

   // Assign all virtual regs that depend on NoReg
   for (i=0; i<numberOfRegisters; i++)
      {
      if (_dependencies[i].getRealRegister() == TR::RealRegister::NoReg && !_dependencies[i].getExcludeGPR0())
         {
         TR::RealRegister *realOne;

         virtReg     = _dependencies[i].getRegister();
         realOne     = virtReg->getAssignedRealRegister();
         if (!realOne)
            {
            machine->assignOneRegister(currentInstruction, virtReg, false);
            }
         virtReg->block();
         }
      }

   unblockRegisters(numberOfRegisters);
   for (i = 0; i < numberOfRegisters; i++)
      {
      TR::Register     *dependentRegister = getRegisterDependency(i)->getRegister();
      // dependentRegister->getAssignedRegister() is NULL if the reg has already been spilled due to a spilledReg dep
      if (comp->getOption(TR_DisableOOL) || (!(cg->isOutOfLineColdPath()) && !(cg->isOutOfLineHotPath())))
         {
         TR_ASSERT(dependentRegister->getAssignedRegister(),
             "assignedRegister can not  be NULL");
         }
      if (dependentRegister->getAssignedRegister())
         {
         TR::RealRegister *assignedRegister = dependentRegister->getAssignedRegister()->getRealRegister();

         if (getRegisterDependency(i)->getRealRegister() == TR::RealRegister::NoReg)
            getRegisterDependency(i)->setRealRegister(toRealRegister(assignedRegister)->getRegisterNumber());

         machine->decFutureUseCountAndUnlatch(dependentRegister);
         }
      }
   }
Exemple #29
0
TR_BitVector *
addVeryRefinedCallAliasSets(TR::ResolvedMethodSymbol * methodSymbol, TR_BitVector * aliases, List<void> * methodsPeeked)
   {
   TR::Compilation *comp = TR::comp();

   void * methodId = methodSymbol->getResolvedMethod()->getPersistentIdentifier();
   if (methodsPeeked->find(methodId))
      {
      // This can't be allocated into the alias region as it must be accessed across optimizations
      TR_BitVector *heapAliases = new (comp->trHeapMemory()) TR_BitVector(comp->getSymRefCount(), comp->trMemory(), heapAlloc, growable);
      *heapAliases |= *aliases;
      return heapAliases;
      }

   // stop if the peek is getting very deep
   //
   if (methodsPeeked->getSize() >= PEEK_THRESHOLD)
      return 0;

   methodsPeeked->add(methodId);

   dumpOptDetails(comp, "O^O REFINING ALIASES: Peeking into the IL to refine aliases \n");

   if (!methodSymbol->getResolvedMethod()->genMethodILForPeeking(methodSymbol, comp, true))
      return 0;

   TR::SymbolReferenceTable * symRefTab = comp->getSymRefTab();
   for (TR::TreeTop * tt = methodSymbol->getFirstTreeTop(); tt; tt = tt->getNextTreeTop())
      {
	   TR::Node *node = tt->getNode();
      if (node->getOpCode().isResolveCheck())
         return 0;

      if ((node->getOpCodeValue() == TR::treetop) ||
          (node->getOpCodeValue() == TR::compressedRefs) ||
          node->getOpCode().isCheck())
         node = node->getFirstChild();

      if (node->getOpCode().isStore())
         {
         TR::SymbolReference * symRefInCallee = node->getSymbolReference(), * symRefInCaller;
         TR::Symbol * symInCallee = symRefInCallee->getSymbol();
         TR::DataType type = symInCallee->getDataType();
         if (symInCallee->isShadow())
            {
            if (symInCallee->isArrayShadowSymbol())
               symRefInCaller = symRefTab->getSymRef(symRefTab->getArrayShadowIndex(type));

            else if (symInCallee->isArrayletShadowSymbol())
               symRefInCaller = symRefTab->getSymRef(symRefTab->getArrayletShadowIndex(type));

            else
               symRefInCaller = symRefTab->findShadowSymbol(symRefInCallee->getOwningMethod(comp), symRefInCallee->getCPIndex(), type);

            if (symRefInCaller)
               {
               if (symRefInCaller->reallySharesSymbol(comp))
                  symRefInCaller->setSharedShadowAliases(aliases, symRefTab);

               aliases->set(symRefInCaller->getReferenceNumber());
               }

            }
         else if (symInCallee->isStatic())
            {
            symRefInCaller = symRefTab->findStaticSymbol(symRefInCallee->getOwningMethod(comp), symRefInCallee->getCPIndex(), type);
            if (symRefInCaller)
               {
               if (symRefInCaller->reallySharesSymbol(comp))
                  symRefInCaller->setSharedStaticAliases(aliases, symRefTab);
               else
                  aliases->set(symRefInCaller->getReferenceNumber());
               }
            }
         }
      else if (node->getOpCode().isCall())
         {
         if (node->getOpCode().isCallIndirect())
            return 0;
         TR::ResolvedMethodSymbol * calleeSymbol = node->getSymbol()->getResolvedMethodSymbol();
         if (!calleeSymbol)
            return 0;
         TR_ResolvedMethod * calleeMethod = calleeSymbol->getResolvedMethod();
         if (!calleeMethod->isCompilable(comp->trMemory()) || calleeMethod->isJNINative())
            return 0;

         if (!addVeryRefinedCallAliasSets(calleeSymbol, aliases, methodsPeeked))
            return 0;
         }
      else if (node->getOpCodeValue() == TR::monent)
         return 0;
      }

   // This can't be allocated into the alias region as it must be accessed across optimizations
   TR_BitVector *heapAliases = new (comp->trHeapMemory()) TR_BitVector(comp->getSymRefCount(), comp->trMemory(), heapAlloc, growable);
   *heapAliases |= *aliases;
   return heapAliases;
   }
Exemple #30
0
TR_BitVector *
OMR::SymbolReference::getUseDefAliasesBV(bool isDirectCall, bool includeGCSafePoint)
   {
   TR::Compilation *comp = TR::comp();
   TR::Region &aliasRegion = comp->aliasRegion();
   int32_t bvInitialSize = comp->getSymRefCount();
   TR_BitVectorGrowable growability = growable;

   // allow more than one shadow for an array type.  Used by LoopAliasRefiner
   const bool supportArrayRefinement=true;

   int32_t kind = _symbol->getKind();
   TR::SymbolReferenceTable * symRefTab = comp->getSymRefTab();

   // !!! NOTE !!!
   // THERE IS A COPY OF THIS LOGIC IN sharesSymbol
   //
   if (!self()->reallySharesSymbol(comp))
      {
      switch (kind)
         {
         case TR::Symbol::IsShadow:
         case TR::Symbol::IsStatic:
            {
            // For unresolved constant dynamic, we need to invoke a Java bootstrap method,
            // which can have arbitrary side effects, so the aliasing should be conservative here.
            // isConstObjectRef now returns true for condy, so we add an explicit condition,
            // more like a short-circuit, to say if we are unresolved and not isConstObjectRef
            // (this is the same as before), or if we are unresolved and condy
            // (this is the extra condition added), we would return conservative aliases.
            if ((self()->isUnresolved() && (_symbol->isConstantDynamic() || !_symbol->isConstObjectRef())) ||
	        _symbol->isVolatile() || self()->isLiteralPoolAddress() ||
                self()->isFromLiteralPool() || _symbol->isUnsafeShadowSymbol() ||
                (_symbol->isArrayShadowSymbol() && comp->getMethodSymbol()->hasVeryRefinedAliasSets()))
               {
               // getUseDefAliases might not return NULL
               }
            else if (!symRefTab->aliasBuilder.mutableGenericIntShadowHasBeenCreated())
               {
               // getUseDefAliases must return NULL
               return NULL;
               }
            else if (kind == TR::Symbol::IsStatic && !symRefTab->aliasBuilder.litPoolGenericIntShadowHasBeenCreated())
               {
               // getUseDefAliases must return NULL
               return NULL;
               }
            break;
            }
         }
      }

   // now do stuff for various kinds of symbols
   //
   switch (kind)
      {
      case TR::Symbol::IsMethod:
         {
         TR::MethodSymbol * methodSymbol = _symbol->castToMethodSymbol();

         if (!methodSymbol->isHelper())
            return symRefTab->aliasBuilder.methodAliases(self());

         if (symRefTab->isNonHelper(self(), TR::SymbolReferenceTable::arraySetSymbol) ||
             symRefTab->isNonHelper(self(), TR::SymbolReferenceTable::osrFearPointHelperSymbol) ||
             symRefTab->isNonHelper(self(), TR::SymbolReferenceTable::potentialOSRPointHelperSymbol))
            {
            return &symRefTab->aliasBuilder.defaultMethodDefAliases();
            }

         if (symRefTab->isNonHelper(self(), TR::SymbolReferenceTable::arrayCmpSymbol))
            return 0;

         switch (self()->getReferenceNumber())
            {
            case TR_methodTypeCheck:
            case TR_nullCheck:
               return &symRefTab->aliasBuilder.defaultMethodDefAliasesWithoutImmutable();

            case TR_arrayBoundsCheck:
            case TR_checkCast:
            case TR_divCheck:
            case TR_typeCheckArrayStore:
            case TR_arrayStoreException:
            case TR_incompatibleReceiver:
            case TR_IncompatibleClassChangeError:
            case TR_reportFinalFieldModified:
            case TR_reportMethodEnter:
            case TR_reportStaticMethodEnter:
            case TR_reportMethodExit:
            case TR_acquireVMAccess:
            case TR_instanceOf:
            case TR_checkAssignable:
            case TR_throwCurrentException:
            case TR_releaseVMAccess:
            case TR_stackOverflow:
            case TR_writeBarrierStore:
            case TR_writeBarrierBatchStore:
            case TR_jitProfileAddress:
            case TR_jitProfileWarmCompilePICAddress:
            case TR_jitProfileValue:
            case TR_jitProfileLongValue:
            case TR_jitProfileBigDecimalValue:
            case TR_jitProfileParseBuffer:

               return 0;

            case TR_asyncCheck:
            case TR_writeBarrierClassStoreRealTimeGC:
            case TR_writeBarrierStoreRealTimeGC:
            case TR_aNewArray:
            case TR_newObject:
            case TR_newObjectNoZeroInit:
            case TR_newArray:
            case TR_multiANewArray:
               if ((comp->generateArraylets() || comp->isDLT()) && includeGCSafePoint)
                  return &symRefTab->aliasBuilder.gcSafePointSymRefNumbers();
               else
                  return 0;

            case TR_aThrow:
               return 0;

            // The monitor exit symbol needs to be aliased with all fields in the
            // current class to ensure that all references to fields are evaluated
            // before the monitor exit
            case TR_monitorExit:
            case TR_monitorEntry:
            case TR_transactionExit:
            case TR_transactionEntry:

            default:
               // The following is the place to check for
               // a use of killsAllMethodSymbolRef... However,
               // it looks like the default action is sufficient.
               //if (symRefTab->findKillsAllMethodSymbolRef() == self())
               //   {
               //   }
               return &symRefTab->aliasBuilder.defaultMethodDefAliases();
            }
         }
      case TR::Symbol::IsResolvedMethod:
         {
         TR::ResolvedMethodSymbol * resolvedMethodSymbol = _symbol->castToResolvedMethodSymbol();

         if (!comp->getOption(TR_EnableHCR))
            {
            switch (resolvedMethodSymbol->getRecognizedMethod())
               {
#ifdef J9_PROJECT_SPECIFIC
               case TR::java_lang_System_arraycopy:
                  {
                  TR_BitVector * aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
                  *aliases |= symRefTab->aliasBuilder.arrayElementSymRefs();
                  if (comp->generateArraylets())
                     *aliases |= symRefTab->aliasBuilder.arrayletElementSymRefs();
                  return aliases;
                  }

                  if (resolvedMethodSymbol->isPureFunction())
                      return NULL;

               case TR::java_lang_Double_longBitsToDouble:
               case TR::java_lang_Double_doubleToLongBits:
               case TR::java_lang_Float_intBitsToFloat:
               case TR::java_lang_Float_floatToIntBits:
               case TR::java_lang_Double_doubleToRawLongBits:
               case TR::java_lang_Float_floatToRawIntBits:
               case TR::java_lang_Math_sqrt:
               case TR::java_lang_StrictMath_sqrt:
               case TR::java_lang_Math_sin:
               case TR::java_lang_StrictMath_sin:
               case TR::java_lang_Math_cos:
               case TR::java_lang_StrictMath_cos:
               case TR::java_lang_Math_max_I:
               case TR::java_lang_Math_min_I:
               case TR::java_lang_Math_max_L:
               case TR::java_lang_Math_min_L:
               case TR::java_lang_Math_abs_I:
               case TR::java_lang_Math_abs_L:
               case TR::java_lang_Math_abs_F:
               case TR::java_lang_Math_abs_D:
               case TR::java_lang_Math_pow:
               case TR::java_lang_StrictMath_pow:
               case TR::java_lang_Math_exp:
               case TR::java_lang_StrictMath_exp:
               case TR::java_lang_Math_log:
               case TR::java_lang_StrictMath_log:
               case TR::java_lang_Math_floor:
               case TR::java_lang_Math_ceil:
               case TR::java_lang_Math_copySign_F:
               case TR::java_lang_Math_copySign_D:
               case TR::java_lang_StrictMath_floor:
               case TR::java_lang_StrictMath_ceil:
               case TR::java_lang_StrictMath_copySign_F:
               case TR::java_lang_StrictMath_copySign_D:
               case TR::com_ibm_Compiler_Internal__TR_Prefetch:
               case TR::java_nio_Bits_keepAlive:
                  if ((comp->generateArraylets() || comp->isDLT()) && includeGCSafePoint)
                     return &symRefTab->aliasBuilder.gcSafePointSymRefNumbers();
                  else
                     return 0;

               // no aliasing on DFP dummy stubs
               case TR::java_math_BigDecimal_DFPPerformHysteresis:
               case TR::java_math_BigDecimal_DFPUseDFP:
               case TR::java_math_BigDecimal_DFPHWAvailable:
               case TR::java_math_BigDecimal_DFPCompareTo:
               case TR::java_math_BigDecimal_DFPUnscaledValue:
               case TR::com_ibm_dataaccess_DecimalData_DFPFacilityAvailable:
               case TR::com_ibm_dataaccess_DecimalData_DFPUseDFP:
               case TR::com_ibm_dataaccess_DecimalData_DFPConvertPackedToDFP:
               case TR::com_ibm_dataaccess_DecimalData_DFPConvertDFPToPacked:
               case TR::com_ibm_dataaccess_DecimalData_createZeroBigDecimal:
               case TR::com_ibm_dataaccess_DecimalData_getlaside:
               case TR::com_ibm_dataaccess_DecimalData_setlaside:
               case TR::com_ibm_dataaccess_DecimalData_getflags:
               case TR::com_ibm_dataaccess_DecimalData_setflags:
                  if (!(
#ifdef TR_TARGET_S390
                     TR::Compiler->target.cpu.getS390SupportsDFP() ||
#endif
                      TR::Compiler->target.cpu.supportsDecimalFloatingPoint()) ||
                      comp->getOption(TR_DisableDFP))
                     return NULL;
#endif //J9_PROJECT_SPECIFIC
               default:
               	break;
               }
            }

#ifdef J9_PROJECT_SPECIFIC
         TR_ResolvedMethod * method = resolvedMethodSymbol->getResolvedMethod();
         TR_PersistentMethodInfo * methodInfo = TR_PersistentMethodInfo::get(method);
         if (methodInfo && (methodInfo->hasRefinedAliasSets() ||
                            comp->getMethodHotness() >= veryHot ||
                            resolvedMethodSymbol->hasVeryRefinedAliasSets()) &&
             (method->isStatic() || method->isFinal() || isDirectCall))
            {
            TR_BitVector * aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
            if ((comp->generateArraylets() || comp->isDLT()) && includeGCSafePoint)
               *aliases |= symRefTab->aliasBuilder.gcSafePointSymRefNumbers();

            if (methodInfo->doesntKillAnything() && !comp->getOption(TR_DisableRefinedAliases))
               return aliases;

            if ((resolvedMethodSymbol->hasVeryRefinedAliasSets() || comp->getMethodHotness() >= hot) &&
                !debug("disableVeryRefinedCallAliasSets"))
               {
               TR_BitVector * exactAliases = 0;

               if (resolvedMethodSymbol->hasVeryRefinedAliasSets())
                  exactAliases = symRefTab->aliasBuilder.getVeryRefinedCallAliasSets(resolvedMethodSymbol);
               else
                  {
                  resolvedMethodSymbol->setHasVeryRefinedAliasSets(true);
                  List<void> methodsPeeked(comp->trMemory());
                  exactAliases = addVeryRefinedCallAliasSets(resolvedMethodSymbol, aliases, &methodsPeeked);
                  symRefTab->aliasBuilder.setVeryRefinedCallAliasSets(resolvedMethodSymbol, exactAliases);
                  }
               if (exactAliases)
                  {
                  return exactAliases;
                  }
               }

            // From here on, we're just checking refined alias info.
            // If refined aliases are disabled, return the conservative answer
            // we would have returned had we never attempted to use refined
            // aliases at all.
            //
            if (comp->getOption(TR_DisableRefinedAliases))
               return symRefTab->aliasBuilder.methodAliases(self());

            if (!methodInfo->doesntKillAddressArrayShadows())
               {

               symRefTab->aliasBuilder.addAddressArrayShadows(aliases);

               if (comp->generateArraylets())
                  aliases->set(symRefTab->getArrayletShadowIndex(TR::Address));
               }

            if (!methodInfo->doesntKillIntArrayShadows())
               {

               symRefTab->aliasBuilder.addIntArrayShadows(aliases);

               if (comp->generateArraylets())
                  {
                  aliases->set(symRefTab->getArrayletShadowIndex(TR::Int32));
                  }
               }

            if (!methodInfo->doesntKillNonIntPrimitiveArrayShadows())
               {

               symRefTab->aliasBuilder.addNonIntPrimitiveArrayShadows(aliases);

               if (comp->generateArraylets())
                  {
                  aliases->set(symRefTab->getArrayletShadowIndex(TR::Int8));
                  aliases->set(symRefTab->getArrayletShadowIndex(TR::Int16));
                  aliases->set(symRefTab->getArrayletShadowIndex(TR::Int32));
                  aliases->set(symRefTab->getArrayletShadowIndex(TR::Int64));
                  aliases->set(symRefTab->getArrayletShadowIndex(TR::Float));
                  aliases->set(symRefTab->getArrayletShadowIndex(TR::Double));
                  }
               }

            if (!methodInfo->doesntKillAddressFields())
               *aliases |= symRefTab->aliasBuilder.addressShadowSymRefs();

            if (!methodInfo->doesntKillIntFields())
               *aliases |= symRefTab->aliasBuilder.intShadowSymRefs();

            if (!methodInfo->doesntKillNonIntPrimitiveFields())
               *aliases |= symRefTab->aliasBuilder.nonIntPrimitiveShadowSymRefs();

            if (!methodInfo->doesntKillAddressStatics())
               *aliases |= symRefTab->aliasBuilder.addressStaticSymRefs();

            if (!methodInfo->doesntKillIntStatics())
               *aliases |= symRefTab->aliasBuilder.intStaticSymRefs();

            if (!methodInfo->doesntKillNonIntPrimitiveStatics())
               *aliases |= symRefTab->aliasBuilder.nonIntPrimitiveStaticSymRefs();

            TR_BitVector *methodAliases = symRefTab->aliasBuilder.methodAliases(self());
            *aliases &= *methodAliases;
            return aliases;
            }
#endif

         return symRefTab->aliasBuilder.methodAliases(self());
         }
      case TR::Symbol::IsShadow:
         {
         if ((self()->isUnresolved() && !_symbol->isConstObjectRef()) || _symbol->isVolatile() || self()->isLiteralPoolAddress() || self()->isFromLiteralPool() ||
             (_symbol->isUnsafeShadowSymbol() && !self()->reallySharesSymbol()))
            {
            if (symRefTab->aliasBuilder.unsafeArrayElementSymRefs().get(self()->getReferenceNumber()))
               {
               TR_BitVector *aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
               *aliases |= comp->getSymRefTab()->aliasBuilder.defaultMethodDefAliasesWithoutImmutable();
               *aliases -= symRefTab->aliasBuilder.cpSymRefs();
               return aliases;
               }
            else
               return &comp->getSymRefTab()->aliasBuilder.defaultMethodDefAliasesWithoutImmutable();
            }

         TR_BitVector *aliases = NULL;
         if (_symbol == symRefTab->findGenericIntShadowSymbol())
            {
            aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
            *aliases |= symRefTab->aliasBuilder.arrayElementSymRefs();
            if (comp->generateArraylets())
               *aliases |= symRefTab->aliasBuilder.arrayletElementSymRefs();
            *aliases |= symRefTab->aliasBuilder.genericIntShadowSymRefs();
            *aliases |= symRefTab->aliasBuilder.genericIntArrayShadowSymRefs();
            *aliases |= symRefTab->aliasBuilder.genericIntNonArrayShadowSymRefs();
            *aliases |= symRefTab->aliasBuilder.unsafeSymRefNumbers();
#ifdef J9_PROJECT_SPECIFIC
            *aliases |= symRefTab->aliasBuilder.unresolvedShadowSymRefs();
#endif
            if (symRefTab->aliasBuilder.conservativeGenericIntShadowAliasing())
               {
               *aliases |= symRefTab->aliasBuilder.addressShadowSymRefs();
               *aliases |= symRefTab->aliasBuilder.intShadowSymRefs();
               *aliases |= symRefTab->aliasBuilder.nonIntPrimitiveShadowSymRefs();
               }
            aliases->set(self()->getReferenceNumber());
            return aliases;
            }

         if (self()->reallySharesSymbol(comp))
            {
            aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
            self()->setSharedShadowAliases(aliases, symRefTab);
            }

         if (symRefTab->findGenericIntShadowSymbol())
            {
            if (!aliases)
               aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
            self()->setLiteralPoolAliases(aliases, symRefTab);

            if (symRefTab->aliasBuilder.conservativeGenericIntShadowAliasing() || self()->isUnresolved())
               {
               *aliases |= symRefTab->aliasBuilder.genericIntShadowSymRefs();
               *aliases |= symRefTab->aliasBuilder.genericIntArrayShadowSymRefs();
               *aliases |= symRefTab->aliasBuilder.genericIntNonArrayShadowSymRefs();
               }
            }

         if (_symbol->isArrayShadowSymbol() &&
             symRefTab->findGenericIntShadowSymbol())
            {
            if (!aliases)
               aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
            *aliases |= symRefTab->aliasBuilder.genericIntShadowSymRefs();
            *aliases |= symRefTab->aliasBuilder.genericIntArrayShadowSymRefs();

            if (supportArrayRefinement && self()->getIndependentSymRefs())
               *aliases -= *self()->getIndependentSymRefs();
            }

#ifdef J9_PROJECT_SPECIFIC
         // make TR::PackedDecimal aliased with TR::Int8(byte)
         if (_symbol->isArrayShadowSymbol() && _symbol->getDataType() == TR::PackedDecimal)
            {
            if (!aliases)
               aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
            aliases->set(symRefTab->getArrayShadowIndex(TR::Int8));
            }
         //the other way around.
         if (_symbol->isArrayShadowSymbol() && _symbol->getDataType() == TR::Int8)
            {
            if (!aliases)
               aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
            aliases->set(symRefTab->getArrayShadowIndex(TR::PackedDecimal));
            }
#endif

         // alias vector arrays shadows  with corresponding scalar array shadows
         if (_symbol->isArrayShadowSymbol() && _symbol->getDataType().isVector())
            {
            if (!aliases)
               aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
            aliases->set(symRefTab->getArrayShadowIndex(_symbol->getDataType().vectorToScalar()));
            }
         // the other way around
         if (_symbol->isArrayShadowSymbol() && !_symbol->getDataType().isVector())
            {
            if (!aliases)
               aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
            aliases->set(symRefTab->getArrayShadowIndex(_symbol->getDataType().scalarToVector()));
            }

         if (_symbol->isArrayShadowSymbol() &&
             !symRefTab->aliasBuilder.immutableArrayElementSymRefs().isEmpty())
            {
            if (!aliases)
               aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);

            TR::DataType type = _symbol->getDataType();
            TR_BitVectorIterator bvi(symRefTab->aliasBuilder.arrayElementSymRefs());
            int32_t symRefNum;
            while (bvi.hasMoreElements())
               {
               symRefNum = bvi.getNextElement();
               if (symRefTab->getSymRef(symRefNum)->getSymbol()->getDataType() == type)
                  aliases->set(symRefNum);
               }
            }

         if (_symbol->isArrayShadowSymbol() &&
             supportArrayRefinement &&
             comp->getMethodSymbol()->hasVeryRefinedAliasSets())
            {
            if (!aliases)
               aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);

            TR::DataType type = _symbol->getDataType();
            TR_BitVectorIterator bvi(symRefTab->aliasBuilder.arrayElementSymRefs());
            int32_t symRefNum;
            while (bvi.hasMoreElements())
               {
               symRefNum = bvi.getNextElement();
               if (symRefTab->getSymRef(symRefNum)->getSymbol()->getDataType() == type)
                  aliases->set(symRefNum);
               }

            if (self()->getIndependentSymRefs())
               *aliases -= *self()->getIndependentSymRefs();

            return aliases;
            }

         if (aliases)
            aliases->set(self()->getReferenceNumber());

         if (symRefTab->aliasBuilder.unsafeArrayElementSymRefs().get(self()->getReferenceNumber()))
            *aliases -= symRefTab->aliasBuilder.cpSymRefs();
         else if (symRefTab->aliasBuilder.cpSymRefs().get(self()->getReferenceNumber()))
            *aliases -= symRefTab->aliasBuilder.unsafeArrayElementSymRefs();

         return aliases;
         }
      case TR::Symbol::IsStatic:
         {
         // For unresolved constant dynamic, we need to invoke a Java bootstrap method,
         // which can have arbitrary side effects, so the aliasing should be conservative here.
         // isConstObjectRef now returns true for condy, so we add an explicit condition,
         // more like a short-circuit, to say if we are unresolved and not isConstObjectRef
         // (this is the same as before), or if we are unresolved and condy
         // (this is the extra condition added), we would return conservative aliases.
         if ((self()->isUnresolved() && (_symbol->isConstantDynamic() || !_symbol->isConstObjectRef())) ||
	     self()->isLiteralPoolAddress() || self()->isFromLiteralPool() || _symbol->isVolatile())
            {
            return &comp->getSymRefTab()->aliasBuilder.defaultMethodDefAliases();
            }

         TR_BitVector *aliases = NULL;
         if (self()->reallySharesSymbol(comp))
            {
            aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
            self()->setSharedStaticAliases(aliases, symRefTab);
            }

         if (symRefTab->findGenericIntShadowSymbol())
            {
            if (!aliases)
               aliases = new (aliasRegion) TR_BitVector(bvInitialSize, aliasRegion, growability);
            self()->setLiteralPoolAliases(aliases, symRefTab);
            }

         if (aliases)
            aliases->set(self()->getReferenceNumber());

         return aliases;
         }
      case TR::Symbol::IsMethodMetaData:
         {
         TR_BitVector *aliases = NULL;
         return aliases;
         }
      default:
         //TR_ASSERT(0, "getUseDefAliasing called for non method");
         if (comp->generateArraylets() && comp->getSymRefTab()->aliasBuilder.gcSafePointSymRefNumbers().get(self()->getReferenceNumber()) && includeGCSafePoint)
            return &comp->getSymRefTab()->aliasBuilder.gcSafePointSymRefNumbers();
         else
            return 0;


      }
   }