示例#1
0
TR::Register *
OMR::ARM64::TreeEvaluator::imulEvaluator(TR::Node *node, TR::CodeGenerator *cg)
   {
   TR::Node *firstChild = node->getFirstChild();
   TR::Register *src1Reg = cg->evaluate(firstChild);
   TR::Node *secondChild = node->getSecondChild();
   TR::Register *trgReg;

   if (secondChild->getOpCode().isLoadConst() && secondChild->getRegister() == NULL)
      {
      int32_t value = secondChild->getInt();
      if (value > 0 && cg->convertMultiplyToShift(node))
         {
         // The multiply has been converted to a shift.
         trgReg = cg->evaluate(node);
         return trgReg;
         }
      else
         {
         trgReg = cg->allocateRegister();
         mulConstant32(node, trgReg, src1Reg, value, cg);
         }
      }
   else
      {
      TR::Register *src2Reg = cg->evaluate(secondChild);
      trgReg = cg->allocateRegister();
      generateMulInstruction(cg, node, trgReg, src1Reg, src2Reg);
      }
   firstChild->decReferenceCount();
   secondChild->decReferenceCount();
   node->setRegister(trgReg);
   return trgReg;
   }
示例#2
0
static TR::Register *addOrSubInteger(TR::Node *node, TR::CodeGenerator *cg)
   {
   TR::Node *firstChild = node->getFirstChild();
   TR::Register *src1Reg = cg->evaluate(firstChild);
   TR::Node *secondChild = node->getSecondChild();
   TR::Register *trgReg = cg->allocateRegister();
   bool isAdd = node->getOpCode().isAdd();

   if (secondChild->getOpCode().isLoadConst() && secondChild->getRegister() == NULL)
      {
      int32_t value = secondChild->getInt();
      if (constantIsUnsignedImm12(value))
         {
         generateTrg1Src1ImmInstruction(cg, isAdd ? TR::InstOpCode::addimmw : TR::InstOpCode::subimmw, node, trgReg, src1Reg, value);
         }
      else
         {
         TR::Register *tmpReg = cg->allocateRegister();
         loadConstant32(cg, node, value, tmpReg);
         generateTrg1Src2Instruction(cg, isAdd ? TR::InstOpCode::addw : TR::InstOpCode::subw, node, trgReg, src1Reg, tmpReg);
         cg->stopUsingRegister(tmpReg);
         }
      }
   else
      {
      TR::Register *src2Reg = cg->evaluate(secondChild);
      generateTrg1Src2Instruction(cg, isAdd ? TR::InstOpCode::addw : TR::InstOpCode::subw, node, trgReg, src1Reg, src2Reg);
      }

   node->setRegister(trgReg);
   firstChild->decReferenceCount();
   secondChild->decReferenceCount();
   return trgReg;
   }
示例#3
0
static TR::Register *shiftHelper(TR::Node *node, TR::ARM64ShiftCode shiftType, TR::CodeGenerator *cg)
   {
   TR::Node *firstChild = node->getFirstChild();
   TR::Node *secondChild = node->getSecondChild();
   TR::ILOpCodes secondOp = secondChild->getOpCodeValue();
   TR::Register *srcReg = cg->evaluate(firstChild);
   TR::Register *trgReg = cg->allocateRegister();
   bool is64bit = node->getDataType().isInt64();
   TR::InstOpCode::Mnemonic op;

   if (secondOp == TR::iconst || secondOp == TR::iuconst)
      {
      int32_t value = secondChild->getInt();
      uint32_t shift = is64bit ? (value & 0x3F) : (value & 0x1F);
      switch (shiftType)
         {
         case TR::SH_LSL:
            generateLogicalShiftLeftImmInstruction(cg, node, trgReg, srcReg, shift);
            break;
         case TR::SH_LSR:
            generateLogicalShiftRightImmInstruction(cg, node, trgReg, srcReg, shift);
            break;
         case TR::SH_ASR:
            generateArithmeticShiftRightImmInstruction(cg, node, trgReg, srcReg, shift);
            break;
         default:
            TR_ASSERT(false, "Unsupported shift type.");
         }
      }
   else
      {
      TR::Register *shiftAmountReg = cg->evaluate(secondChild);
      switch (shiftType)
         {
         case TR::SH_LSL:
            op = is64bit ? TR::InstOpCode::lslvx : TR::InstOpCode::lslvw;
            break;
         case TR::SH_LSR:
            op = is64bit ? TR::InstOpCode::lsrvx : TR::InstOpCode::lsrvw;
            break;
         case TR::SH_ASR:
            op = is64bit ? TR::InstOpCode::asrvx : TR::InstOpCode::asrvw;
            break;
         default:
            TR_ASSERT(false, "Unsupported shift type.");
         }
      generateTrg1Src2Instruction(cg, op, node, trgReg, srcReg, shiftAmountReg);
      }

   node->setRegister(trgReg);
   firstChild->decReferenceCount();
   secondChild->decReferenceCount();
   return trgReg;
   }
示例#4
0
TR::Register *
OMR::ARM64::TreeEvaluator::imulhEvaluator(TR::Node *node, TR::CodeGenerator *cg)
   {
   TR::Node *firstChild = node->getFirstChild();
   TR::Register *src1Reg = cg->evaluate(firstChild);
   TR::Node *secondChild = node->getSecondChild();
   TR::Register *src2Reg;
   TR::Register *trgReg = cg->allocateRegister();
   TR::Register *tmpReg = NULL;

   TR::Register *zeroReg = cg->allocateRegister();
   TR::RegisterDependencyConditions *cond = new (cg->trHeapMemory()) TR::RegisterDependencyConditions(1, 1, cg->trMemory());
   addDependency(cond, zeroReg, TR::RealRegister::xzr, TR_GPR, cg);

   // imulh is generated for constant idiv and the second child is the magic number
   // assume magic number is usually a large odd number with little optimization opportunity
   if (secondChild->getOpCode().isLoadConst() && secondChild->getRegister() == NULL)
      {
      int32_t value = secondChild->getInt();
      src2Reg = tmpReg = cg->allocateRegister();
      loadConstant32(cg, node, value, src2Reg);
      }
   else
      {
      src2Reg = cg->evaluate(secondChild);
      }

   generateTrg1Src3Instruction(cg, TR::InstOpCode::smaddl, node, trgReg, src1Reg, src2Reg, zeroReg, cond);
   cg->stopUsingRegister(zeroReg);
   /* logical shift right by 32 bits */
   uint32_t imm = 0x183F; // N=1, immr=32, imms=63
   generateTrg1Src1ImmInstruction(cg, TR::InstOpCode::ubfmx, node, trgReg, trgReg, imm);

   if (tmpReg)
      {
      cg->stopUsingRegister(tmpReg);
      }

   firstChild->decReferenceCount();
   secondChild->decReferenceCount();
   node->setRegister(trgReg);
   return trgReg;
   }
示例#5
0
// also handles lrol
TR::Register *
OMR::ARM64::TreeEvaluator::irolEvaluator(TR::Node *node, TR::CodeGenerator *cg)
   {
   TR::Node *firstChild = node->getFirstChild();
   TR::Node *secondChild = node->getSecondChild();
   TR::Register *trgReg = cg->gprClobberEvaluate(firstChild);
   bool is64bit = node->getDataType().isInt64();
   TR::InstOpCode::Mnemonic op;

   if (secondChild->getOpCode().isLoadConst())
      {
      int32_t value = secondChild->getInt();
      uint32_t shift = is64bit ? (value & 0x3F) : (value & 0x1F);

      if (shift != 0)
         {
         shift = is64bit ? (64 - shift) : (32 - shift); // change ROL to ROR
         op = is64bit ? TR::InstOpCode::extrx : TR::InstOpCode::extrw; // ROR is an alias of EXTR
         generateTrg1Src2ShiftedInstruction(cg, op, node, trgReg, trgReg, trgReg, TR::SH_LSL, shift);
         }
      }
   else
      {
      TR::Register *shiftAmountReg = cg->evaluate(secondChild);
      generateNegInstruction(cg, node, shiftAmountReg, shiftAmountReg); // change ROL to ROR
      if (is64bit)
         {
         // 32->64 bit sign extension: SXTW is alias of SBFM
         uint32_t imm = 0x101F; // N=1, immr=0, imms=31
         generateTrg1Src1ImmInstruction(cg, TR::InstOpCode::sbfmx, node, shiftAmountReg, shiftAmountReg, imm);
         }
      op = is64bit ? TR::InstOpCode::rorvx : TR::InstOpCode::rorvw;
      generateTrg1Src2Instruction(cg, op, node, trgReg, trgReg, shiftAmountReg);
      }

   node->setRegister(trgReg);
   firstChild->decReferenceCount();
   secondChild->decReferenceCount();
   return trgReg;
   }
示例#6
0
uint8_t *TR::PPCArrayCopyCallSnippet::emitSnippetBody()
   {
   TR::Node *node = getNode();
   TR_ASSERT(node->getOpCodeValue() == TR::arraycopy &&
          node->getChild(2)->getOpCode().isLoadConst(), "only valid for arraycopies with a constant length\n");

   uint8_t *buffer = cg()->getBinaryBufferCursor();
   getSnippetLabel()->setCodeLocation(buffer);
   TR::RealRegister *lengthReg = cg()->machine()->getRealRegister(_lengthRegNum);
   TR::Node *lengthNode = node->getChild(2);
   int64_t byteLen = (lengthNode->getType().isInt32() ?
                      lengthNode->getInt() : lengthNode->getLongInt());
   TR::InstOpCode opcode;

   // li lengthReg, #byteLen
   opcode.setOpCodeValue(TR::InstOpCode::li);
   buffer = opcode.copyBinaryToBuffer(buffer);
   lengthReg->setRegisterFieldRT((uint32_t *)buffer);
   TR_ASSERT(byteLen <= UPPER_IMMED,"byteLen too big to encode\n");
   *(int32_t *)buffer |= byteLen;
   buffer += 4;

   return TR::PPCHelperCallSnippet::genHelperCall(buffer);
   }
示例#7
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);
      }
   }
示例#8
0
bool
OMR::Simplifier::isBoundDefinitelyGELength(TR::Node *boundChild, TR::Node *lengthChild)
   {
   TR::ILOpCodes boundOp = boundChild->getOpCodeValue();
   if (boundOp == TR::iadd)
      {
      TR::Node *first  = boundChild->getFirstChild();
      TR::Node *second = boundChild->getSecondChild();
      if (first == lengthChild)
         {
         TR::ILOpCodes secondOp = second->getOpCodeValue();
         if (second->getOpCode().isArrayLength()                          ||
             secondOp == TR::bu2i                                          ||
             secondOp == TR::su2i                                          ||

             (secondOp == TR::iconst &&
              second->getInt() >= 0)                                      ||

             (secondOp == TR::iand                                     &&
              second->getSecondChild()->getOpCodeValue() == TR::iconst &&
              (second->getSecondChild()->getInt() & 80000000) == 0)       ||

             (secondOp == TR::iushr                                    &&
              second->getSecondChild()->getOpCodeValue() == TR::iconst &&
              (second->getSecondChild()->getInt() & 0x1f) > 0))
            {
            return true;
            }
         }
      else if (second == lengthChild)
         {
         TR::ILOpCodes firstOp = first->getOpCodeValue();
         if (first->getOpCode().isArrayLength()                          ||
             firstOp == TR::bu2i                                          ||
             firstOp == TR::su2i                                          ||

             (firstOp == TR::iand                                     &&
              first->getSecondChild()->getOpCodeValue() == TR::iconst &&
              (first->getSecondChild()->getInt() & 80000000) == 0)       ||

             (firstOp == TR::iushr &&
              first->getSecondChild()->getOpCodeValue() == TR::iconst &&
              (first->getSecondChild()->getInt() & 0x1f) > 0))
            {
            return true;
            }
         }
      }
   else if (boundOp == TR::isub)
      {
      TR::Node *first  = boundChild->getFirstChild();
      TR::Node *second = boundChild->getSecondChild();
      if (first  == lengthChild)
         {
         TR::ILOpCodes secondOp = second->getOpCodeValue();
         if ((secondOp == TR::iconst &&
              second->getInt() < 0)                                      ||

             (secondOp == TR::ior                                      &&
              second->getSecondChild()->getOpCodeValue() == TR::iconst &&
              (second->getSecondChild()->getInt() & 0x80000000) != 0))
            {
            return true;
            }
         }
      }

   return false;
   }
示例#9
0
TR_ExpressionsSimplification::LoopInfo*
TR_ExpressionsSimplification::findLoopInfo(TR_RegionStructure* region)
   {
   ListIterator<TR::CFGEdge> exitEdges(&region->getExitEdges());

   if (region->getExitEdges().getSize() != 1)
      {
      if (trace())
         traceMsg(comp(), "Region with more than 1 exit edges can't be handled\n");
      return 0;
      }

   TR_StructureSubGraphNode* exitNode = toStructureSubGraphNode(exitEdges.getFirst()->getFrom());

   if (!exitNode->getStructure()->asBlock())
      {
      if (trace())
         traceMsg(comp(), "The exit block can't be found\n");
      return 0;
      }

   TR::Block *exitBlock = exitNode->getStructure()->asBlock()->getBlock();
   TR::Node *lastTreeInExitBlock = exitBlock->getLastRealTreeTop()->getNode();

   if (trace())
      {
      traceMsg(comp(), "The exit block is %d\n", exitBlock->getNumber());
      traceMsg(comp(), "The branch node is %p\n", lastTreeInExitBlock);
      }


   if (!lastTreeInExitBlock->getOpCode().isBranch())
      {
      if (trace())
         traceMsg(comp(), "The branch node couldn't be found\n");
      return 0;
      }

   if (lastTreeInExitBlock->getNumChildren() < 2)
      {
      if (trace())
         traceMsg(comp(), "The branch node has less than 2 children\n");
      return 0;
      }

   TR::Node *firstChildOfLastTree = lastTreeInExitBlock->getFirstChild();
   TR::Node *secondChildOfLastTree = lastTreeInExitBlock->getSecondChild();

   if (!firstChildOfLastTree->getOpCode().hasSymbolReference())
      {
      if (trace())
         traceMsg(comp(), "The branch node's first child node %p - its opcode does not have a symbol reference\n", firstChildOfLastTree);
      return 0;
      }

   TR::SymbolReference *firstChildSymRef = firstChildOfLastTree->getSymbolReference();

   if (trace())
      traceMsg(comp(), "Symbol Reference: %p Symbol: %p\n", firstChildSymRef, firstChildSymRef->getSymbol());

   // Locate the induction variable that matches with the exit node symbol
   //
   TR_InductionVariable *indVar = region->findMatchingIV(firstChildSymRef);
   if (!indVar) return 0;

   if (!indVar->getIncr()->asIntConst())
      {
      if (trace())
         traceMsg(comp(), "Increment is not a constant\n");
      return 0;
      }

   int32_t increment = indVar->getIncr()->getLowInt();

   _visitCount = comp()->incVisitCount();
   bool indVarWrittenAndUsedUnexpectedly = false;
   if (firstChildOfLastTree->getReferenceCount() > 1)
      {
      TR::TreeTop *cursorTreeTopInExitBlock = exitBlock->getEntry();
      TR::TreeTop *exitTreeTopInExitBlock = exitBlock->getExit();

      bool loadSeen = false;
      while (cursorTreeTopInExitBlock != exitTreeTopInExitBlock)
         {
         TR::Node *cursorNode = cursorTreeTopInExitBlock->getNode();
         if (checkForLoad(cursorNode, firstChildOfLastTree))
            loadSeen = true;

         if (!cursorNode->getOpCode().isStore() &&
             (cursorNode->getNumChildren() > 0))
           cursorNode = cursorNode->getFirstChild();

         if (cursorNode->getOpCode().isStore() &&
             (cursorNode->getSymbolReference() == firstChildSymRef))
            {
            indVarWrittenAndUsedUnexpectedly = true;
            if ((cursorNode->getFirstChild() == firstChildOfLastTree) ||
                !loadSeen)
               indVarWrittenAndUsedUnexpectedly = false;
            else
               break;
            }

         cursorTreeTopInExitBlock = cursorTreeTopInExitBlock->getNextTreeTop();
         }
      }

   if (indVarWrittenAndUsedUnexpectedly)
      {
      return 0;
      }

   int32_t lowerBound;
   int32_t upperBound = 0;
   TR::Node *bound = 0;
   bool equals = false;

   switch(lastTreeInExitBlock->getOpCodeValue())
      {
      case TR::ificmplt:
      case TR::ificmpgt:
         equals = true;
      case TR::ificmple:
      case TR::ificmpge:
         if (!(indVar->getEntry() && indVar->getEntry()->asIntConst()))
            {
            if (trace())
               traceMsg(comp(), "Entry value is not a constant\n");
            return 0;
            }
         lowerBound = indVar->getEntry()->getLowInt();

         if (secondChildOfLastTree->getOpCode().isLoadConst())
            {
            upperBound = secondChildOfLastTree->getInt();
            }
         else if (secondChildOfLastTree->getOpCode().isLoadVar())
            {
            bound = secondChildOfLastTree;
            }
         else
            {
            if (trace())
               traceMsg(comp(), "Second child is not a const or a load\n");
            return 0;
            }
         return new (trStackMemory()) LoopInfo(bound, lowerBound, upperBound, increment, equals);


      default:
         if (trace())
            traceMsg(comp(), "The condition has not been implemeted\n");
         return 0;
      }

   return 0;
   }
示例#10
0
TR::Register* OMR::X86::TreeEvaluator::SIMDgetvelemEvaluator(TR::Node* node, TR::CodeGenerator* cg)
   {
   TR::Node* firstChild = node->getChild(0);
   TR::Node* secondChild = node->getChild(1);

   TR::Register* srcVectorReg = cg->evaluate(firstChild);
   TR::Register* resReg = 0;
   TR::Register* lowResReg = 0;
   TR::Register* highResReg = 0;

   int32_t elementCount = -1;
   switch (firstChild->getDataType())
      {
      case TR::VectorInt8:
      case TR::VectorInt16:
         TR_ASSERT(false, "unsupported vector type %s in SIMDgetvelemEvaluator.\n", firstChild->getDataType().toString());
         break;
      case TR::VectorInt32:
         elementCount = 4;
         resReg = cg->allocateRegister();
         break;
      case TR::VectorInt64:
         elementCount = 2;
         if (TR::Compiler->target.is32Bit())
            {
            lowResReg = cg->allocateRegister();
            highResReg = cg->allocateRegister();
            resReg = cg->allocateRegisterPair(lowResReg, highResReg);
            }
         else
            {
            resReg = cg->allocateRegister();
            }
         break;
      case TR::VectorFloat:
         elementCount = 4;
         resReg = cg->allocateSinglePrecisionRegister(TR_FPR);
         break;
      case TR::VectorDouble:
         elementCount = 2;
         resReg = cg->allocateRegister(TR_FPR);
         break;
      default:
         TR_ASSERT(false, "unrecognized vector type %s in SIMDgetvelemEvaluator.\n", firstChild->getDataType().toString());
      }

   if (secondChild->getOpCode().isLoadConst())
      {
      int32_t elem = secondChild->getInt();

      TR_ASSERT(elem >= 0 && elem < elementCount, "Element can only be 0 to %u\n", elementCount - 1);

      uint8_t shufconst = 0x00;
      TR::Register* dstReg = 0;
      if (4 == elementCount)
         {
         /*
          * if elem = 0, access the most significant 32 bits (set shufconst to 0x03)
          * if elem = 1, access the second most significant 32 bits (set shufconst to 0x02)
          * if elem = 2, access the third most significant 32 bits (set shufconst to 0x01)
          * if elem = 3, access the least significant 32 bits (set shufconst to 0x00)
          */
         shufconst = (uint8_t)((3 - elem) & 0x03);

         /*
          * the value to be read (indicated by shufconst) from srcVectorReg is splatted into all 4 slots in the dstReg
          * this puts the value we want in the least significant bits and the other bits should never be read.
          * for float, dstReg and resReg are the same because PSHUFD can work directly with TR_FPR registers
          * for Int32, the result needs to be moved from the dstReg to a TR_GPR resReg.
          */
         if (TR::VectorInt32 == firstChild->getDataType())
            {
            dstReg = cg->allocateRegister(TR_VRF);
            }
         else //TR::VectorFloat == firstChild->getDataType()
            {
            dstReg = resReg;
            }

         /*
          * if elem = 3, the value we want is already in the least significant 32 bits
          * as a result, a mov instruction is good enough and splatting the value is unnecessary
          */
         if (3 == elem)
            {
            generateRegRegInstruction(MOVDQURegReg, node, dstReg, srcVectorReg, cg);
            }
         else
            {
            generateRegRegImmInstruction(PSHUFDRegRegImm1, node, dstReg, srcVectorReg, shufconst, cg);
            }

         if (TR::VectorInt32 == firstChild->getDataType())
            {
            generateRegRegInstruction(MOVDReg4Reg, node, resReg, dstReg, cg);
            cg->stopUsingRegister(dstReg);
            }
         }
      else //2 == elementCount
         {
         /*
          * for double, dstReg and resReg are the same because PSHUFD can work directly with TR_FPR registers
          * for Int64, the result needs to be moved from the dstReg to a TR_GPR resReg.
          */
         if (TR::VectorInt64 == firstChild->getDataType())
            {
            dstReg = cg->allocateRegister(TR_VRF);
            }
         else //TR::VectorDouble == firstChild->getDataType()
            {
            dstReg = resReg;
            }

         /*
          * the value to be read needs to be in the least significant 64 bits.
          * if elem = 0, the value we want is in the most significant 64 bits and needs to be splatted into
          * the least significant 64 bits (the other bits affected by the splat are never read)
          * if elem = 1, the value we want is already in the least significant 64 bits
          * as a result, a mov instruction is good enough and splatting the value is unnecessary
          */
         if (1 == elem)
            {
            generateRegRegInstruction(MOVDQURegReg, node, dstReg, srcVectorReg, cg);
            }
         else //0 == elem
            {
            generateRegRegImmInstruction(PSHUFDRegRegImm1, node, dstReg, srcVectorReg, 0x0e, cg);
            }

         if (TR::VectorInt64 == firstChild->getDataType())
            {
            if (TR::Compiler->target.is32Bit())
               {
               generateRegRegInstruction(MOVDReg4Reg, node, lowResReg, dstReg, cg);
               generateRegRegImmInstruction(PSHUFDRegRegImm1, node, dstReg, srcVectorReg, (0 == elem) ? 0x03 : 0x01, cg);
               generateRegRegInstruction(MOVDReg4Reg, node, highResReg, dstReg, cg);
               }
            else
               {
               generateRegRegInstruction(MOVQReg8Reg, node, resReg, dstReg, cg);
               }
            cg->stopUsingRegister(dstReg);
            }
         }
      }
   else
      {
      //TODO: handle non-constant second child case
      TR_ASSERT(false, "non-const second child not currently supported in SIMDgetvelemEvaluator.\n");
      }

   node->setRegister(resReg);
   cg->decReferenceCount(firstChild);
   cg->decReferenceCount(secondChild);

   return resReg;
   }