Esempio n. 1
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());
   }
Esempio n. 2
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());
   }
Esempio n. 3
0
void
OMR::CodeGenPhase::performInstructionSelectionPhase(TR::CodeGenerator * cg, TR::CodeGenPhase * phase)
   {
   TR::Compilation* comp = cg->comp();
   phase->reportPhase(InstructionSelectionPhase);

   if (comp->getOption(TR_TraceCG) || comp->getOption(TR_TraceTrees) || comp->getOptions()->getTraceCGOption(TR_TraceCGPreInstructionSelection))
      comp->dumpMethodTrees("Pre Instruction Selection Trees");

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

   cg->doInstructionSelection();

   if (comp->getOption(TR_TraceCG) || comp->getOptions()->getTraceCGOption(TR_TraceCGPostInstructionSelection))
      comp->getDebug()->dumpMethodInstrs(comp->getOutFile(), "Post Instruction Selection Instructions", false, true);

   // check reference counts
#if defined(DEBUG) || defined(PROD_WITH_ASSUMES)
      for (int r=0; r<NumRegisterKinds; r++)
         {
         if (TO_KIND_MASK(r) & cg->getSupportedLiveRegisterKinds())
            {
            cg->checkForLiveRegisters(cg->getLiveRegisters((TR_RegisterKinds)r));
            }
         }
#endif

   // check interrupt
   if (comp->compilationShouldBeInterrupted(AFTER_INSTRUCTION_SELECTION_CONTEXT))
      {
      comp->failCompilation<TR::CompilationInterrupted>("interrupted after instruction selection");
      }
   }
Esempio n. 4
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);
   }
Esempio n. 5
0
void
OMR::CodeGenPhase::performEmitSnippetsPhase(TR::CodeGenerator * cg, TR::CodeGenPhase * phase)
   {
   TR::Compilation * comp = cg->comp();
   phase->reportPhase(EmitSnippetsPhase);

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

   cg->emitSnippets();

   if (comp->getOption(TR_EnableOSR))
      {
      comp->getOSRCompilationData()->checkOSRLimits();
      comp->getOSRCompilationData()->compressInstruction2SharedSlotMap();
      }

   if (comp->getOption(TR_TraceCG) || comp->getOptions()->getTraceCGOption(TR_TraceCGPostBinaryEncoding))
      {
      diagnostic("\nbuffer start = %8x, code start = %8x, buffer length = %d", cg->getBinaryBufferStart(), cg->getCodeStart(), cg->getEstimatedCodeLength());
      diagnostic("\n");
      const char * title = "Post Binary Instructions";

      comp->getDebug()->dumpMethodInstrs(comp->getOutFile(), title, false, true);

      traceMsg(comp,"<snippets>");
      comp->getDebug()->print(comp->getOutFile(), cg->getSnippetList());
      traceMsg(comp,"\n</snippets>\n");

      auto iterator = cg->getSnippetList().begin();
      int32_t estimatedSnippetStart = cg->getEstimatedSnippetStart();
      while (iterator != cg->getSnippetList().end())
         {
         estimatedSnippetStart += (*iterator)->getLength(estimatedSnippetStart);
         ++iterator;
         }
      int32_t snippetLength = estimatedSnippetStart - cg->getEstimatedSnippetStart();

      diagnostic("\nAmount of code memory allocated for this function        = %d"
                  "\nAmount of code memory consumed for this function         = %d"
                  "\nAmount of snippet code memory consumed for this function = %d\n\n",
                  cg->getEstimatedCodeLength(),
                  cg->getCodeLength(),
                  snippetLength);
      }
   }
Esempio n. 6
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);
   }
Esempio n. 7
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();

   }
Esempio n. 8
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);
      }
   }
Esempio n. 9
0
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);
         }
      }
   }
Esempio n. 10
0
void
OMR::CodeGenPhase::performProcessRelocationsPhase(TR::CodeGenerator * cg, TR::CodeGenPhase * phase)
   {
   TR::Compilation * comp = cg->comp();

   if (comp->getPersistentInfo()->isRuntimeInstrumentationEnabled())
      {
      // This must be called before relocations to generate the relocation data for the profiled instructions.
      cg->createHWPRecords();
      }

   phase->reportPhase(ProcessRelocationsPhase);

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

   cg->processRelocations();

   cg->resizeCodeMemory();
   cg->registerAssumptions();

   cg->syncCode(cg->getBinaryBufferStart(), cg->getBinaryBufferCursor() - cg->getBinaryBufferStart());

   if (comp->getOption(TR_EnableOSR))
     {
     if (comp->getOption(TR_TraceOSR) && !comp->getOption(TR_DisableOSRSharedSlots))
        {
        (*comp) << "OSRCompilationData is " << *comp->getOSRCompilationData() << "\n";
        }
     }

   if (comp->getOption(TR_AOT) && (comp->getOption(TR_TraceRelocatableDataCG) || comp->getOption(TR_TraceRelocatableDataDetailsCG) || comp->getOption(TR_TraceReloCG)))
     {
     traceMsg(comp, "\n<relocatableDataCG>\n");
     if (comp->getOption(TR_TraceRelocatableDataDetailsCG)) // verbose output
        {
        uint8_t * relocatableMethodCodeStart = (uint8_t *)comp->getRelocatableMethodCodeStart();
        traceMsg(comp, "Code start = %8x, Method start pc = %x, Method start pc offset = 0x%x\n", relocatableMethodCodeStart, cg->getCodeStart(), cg->getCodeStart() - relocatableMethodCodeStart);
        }
     cg->getAheadOfTimeCompile()->dumpRelocationData();
     traceMsg(comp, "</relocatableDataCG>\n");
     }

     if (debug("dumpCodeSizes"))
        {
        diagnostic("%08d   %s\n", cg->getCodeLength(), comp->signature());
        }

     if (comp->getCurrentMethod() == NULL)
        {
        comp->getMethodSymbol()->setMethodAddress(cg->getBinaryBufferStart());
        }

     TR_ASSERT(cg->getCodeLength() <= cg->getEstimatedCodeLength(),
               "Method length estimate must be conservatively large\n"
               "    codeLength = %d, estimatedCodeLength = %d \n",
               cg->getCodeLength(), cg->getEstimatedCodeLength()
               );

     // also trace the interal stack atlas
     cg->getStackAtlas()->close(cg);

     TR::SimpleRegex * regex = comp->getOptions()->getSlipTrap();
     if (regex && TR::SimpleRegex::match(regex, comp->getCurrentMethod()))
        {
        if (TR::Compiler->target.is64Bit())
        {
        setDllSlip((char*)cg->getCodeStart(),(char*)cg->getCodeStart()+cg->getCodeLength(),"SLIPDLL64", comp);
        }
     else
        {
        setDllSlip((char*)cg->getCodeStart(),(char*)cg->getCodeStart()+cg->getCodeLength(),"SLIPDLL31", comp);
        }
     }
   if (comp->getOption(TR_TraceCG) || comp->getOptions()->getTraceCGOption(TR_TraceCGPostBinaryEncoding))
      {
      const char * title = "Post Relocation Instructions";
      comp->getDebug()->dumpMethodInstrs(comp->getOutFile(), title, false, true);

      traceMsg(comp,"<snippets>");
      comp->getDebug()->print(comp->getOutFile(), cg->getSnippetList());
      traceMsg(comp,"\n</snippets>\n");

      auto iterator = cg->getSnippetList().begin();
      int32_t estimatedSnippetStart = cg->getEstimatedSnippetStart();
      while (iterator != cg->getSnippetList().end())
         {
         estimatedSnippetStart += (*iterator)->getLength(estimatedSnippetStart);
         ++iterator;
         }
      }
   }
Esempio n. 11
0
void TR_ARMRegisterDependencyGroup::assignRegisters(TR::Instruction  *currentInstruction,
                                                    TR_RegisterKinds kindToBeAssigned,
                                                    uint32_t         numberOfRegisters,
                                                    TR::CodeGenerator *cg)
   {
   TR::Compilation *comp = cg->comp();
   TR::Machine *machine = cg->machine();
   TR::Register  *virtReg;
   TR::RealRegister::RegNum dependentRegNum;
   TR::RealRegister *dependentRealReg, *assignedRegister;
   uint32_t i, j;
   bool changed;

   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_ARMOpCodes opCode;
               TR_RegisterKinds rk = virtReg->getKind();
               switch (rk)
                  {
                  case TR_GPR:
                     opCode = ARMOp_ldr;
                     break;
                  case TR_FPR:
                     opCode = virtReg->isSinglePrecision() ? ARMOp_ldfs : ARMOp_ldfd;
                     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", cg->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::ARMLabelInstruction *labelInstr = (TR::ARMLabelInstruction *)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++)
      {
      virtReg = dependencies[i].getRegister();

      if (virtReg->getAssignedRealRegister()!=NULL)
         {
         if (dependencies[i].getRealRegister() == TR::RealRegister::NoReg)
            {
            virtReg->block();
            }
         else
            {
            dependentRegNum = toRealRegister(virtReg->getAssignedRealRegister())->getRegisterNumber();
            for (j=0; j<numberOfRegisters; j++)
               {
               if (dependentRegNum == dependencies[j].getRealRegister())
                  {
                  virtReg->block();
                  break;
                  }
               }
            }
         }
      }

   do
      {
      changed = false;
      for (i = 0; i < numberOfRegisters; i++)
         {
         virtReg = dependencies[i].getRegister();
         dependentRegNum = dependencies[i].getRealRegister();
         dependentRealReg = machine->getRealRegister(dependentRegNum);

         if (dependentRegNum != TR::RealRegister::NoReg &&
             dependentRegNum != TR::RealRegister::SpilledReg &&
             dependentRealReg->getState() == TR::RealRegister::Free)
            {
            machine->coerceRegisterAssignment(currentInstruction, virtReg, dependentRegNum);
            virtReg->block();
            changed = true;
            }
         }
      } while (changed == true);


   do
      {
      changed = false;
      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->getRealRegister(dependentRegNum);
         if (dependentRegNum != TR::RealRegister::NoReg &&
             dependentRegNum != TR::RealRegister::SpilledReg &&
             dependentRealReg != assignedRegister)
            {
            machine->coerceRegisterAssignment(currentInstruction, virtReg, dependentRegNum);
            virtReg->block();
            changed = true;
            }
         }
      } while (changed == true);

   for (i=0; i<numberOfRegisters; i++)
      {
      if (dependencies[i].getRealRegister() == TR::RealRegister::NoReg)
         {
         bool excludeGPR0 = dependencies[i].getExcludeGPR0()?true:false;
         TR::RealRegister *realOne;

         virtReg = dependencies[i].getRegister();
         realOne = virtReg->getAssignedRealRegister();
         if (realOne!=NULL && excludeGPR0 && toRealRegister(realOne)->getRegisterNumber()==TR::RealRegister::gr0)
            {
            if ((assignedRegister = machine->findBestFreeRegister(virtReg->getKind(), true)) == NULL)
               {
               assignedRegister = machine->freeBestRegister(currentInstruction, virtReg->getKind(), NULL, true);
               }
            machine->coerceRegisterAssignment(currentInstruction, virtReg, assignedRegister->getRegisterNumber());
            }
         else if (realOne == NULL)
            {
            if (virtReg->getTotalUseCount() == virtReg->getFutureUseCount())
               {
               if ((assignedRegister = machine->findBestFreeRegister(virtReg->getKind(), excludeGPR0, true)) == NULL)
                  {
                  assignedRegister = machine->freeBestRegister(currentInstruction, virtReg->getKind(), NULL, excludeGPR0);
                  }
               }
            else
               {
               assignedRegister = machine->reverseSpillState(currentInstruction, virtReg, NULL, excludeGPR0);
               }
            virtReg->setAssignedRegister(assignedRegister);
            assignedRegister->setAssignedRegister(virtReg);
            assignedRegister->setState(TR::RealRegister::Assigned);
            virtReg->block();
            }
         }
      }

   unblockRegisters(numberOfRegisters);
   for (i = 0; i < numberOfRegisters; i++)
      {
      TR::Register *dependentRegister = getRegisterDependency(i)->getRegister();
      if (dependentRegister->getAssignedRegister())
      	 {
         TR::RealRegister *assignedRegister = dependentRegister->getAssignedRegister()->getRealRegister();

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

         if (dependentRegister->decFutureUseCount() == 0)
            {
            dependentRegister->setAssignedRegister(NULL);
            assignedRegister->setAssignedRegister(NULL);
            assignedRegister->setState(TR::RealRegister::Unlatched); // Was setting to Free
            }
         }
      }
   }