Mercurial > jdk8-mips64-public > hotspot / file revision

 /*

  * Copyright 2000-2008 Sun Microsystems, Inc.  All Rights Reserved.

  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.

  *

  * This code is free software; you can redistribute it and/or modify it

  * under the terms of the GNU General Public License version 2 only, as

  * published by the Free Software Foundation.

  *

  * This code is distributed in the hope that it will be useful, but WITHOUT

  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or

  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License

  * version 2 for more details (a copy is included in the LICENSE file that

  * accompanied this code).

  *

  * You should have received a copy of the GNU General Public License version

  * 2 along with this work; if not, write to the Free Software Foundation,

  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.

  *

  * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,

  * CA 95054 USA or visit www.sun.com if you need additional information or

  * have any questions.

  *

  */

 # include "incls/_precompiled.incl"

 # include "incls/_c1_LIR.cpp.incl"

 Register LIR_OprDesc::as_register() const {

   return FrameMap::cpu_rnr2reg(cpu_regnr());

 }

 Register LIR_OprDesc::as_register_lo() const {

   return FrameMap::cpu_rnr2reg(cpu_regnrLo());

 }

 Register LIR_OprDesc::as_register_hi() const {

   return FrameMap::cpu_rnr2reg(cpu_regnrHi());

 }

 #if defined(X86)

 XMMRegister LIR_OprDesc::as_xmm_float_reg() const {

   return FrameMap::nr2xmmreg(xmm_regnr());

 }

 XMMRegister LIR_OprDesc::as_xmm_double_reg() const {

   assert(xmm_regnrLo() == xmm_regnrHi(), "assumed in calculation");

   return FrameMap::nr2xmmreg(xmm_regnrLo());

 }

 #endif // X86

 #ifdef SPARC

 FloatRegister LIR_OprDesc::as_float_reg() const {

   return FrameMap::nr2floatreg(fpu_regnr());

 }

 FloatRegister LIR_OprDesc::as_double_reg() const {

   return FrameMap::nr2floatreg(fpu_regnrHi());

 }

 #endif

 LIR_Opr LIR_OprFact::illegalOpr = LIR_OprFact::illegal();

 LIR_Opr LIR_OprFact::value_type(ValueType* type) {

   ValueTag tag = type->tag();

   switch (tag) {

   case objectTag : {

     ClassConstant* c = type->as_ClassConstant();

     if (c != NULL && !c->value()->is_loaded()) {

       return LIR_OprFact::oopConst(NULL);

     } else {

       return LIR_OprFact::oopConst(type->as_ObjectType()->encoding());

     }

   }

   case addressTag: return LIR_OprFact::intConst(type->as_AddressConstant()->value());

   case intTag    : return LIR_OprFact::intConst(type->as_IntConstant()->value());

   case floatTag  : return LIR_OprFact::floatConst(type->as_FloatConstant()->value());

   case longTag   : return LIR_OprFact::longConst(type->as_LongConstant()->value());

   case doubleTag : return LIR_OprFact::doubleConst(type->as_DoubleConstant()->value());

   default: ShouldNotReachHere(); return LIR_OprFact::intConst(-1);

   }

 }

 LIR_Opr LIR_OprFact::dummy_value_type(ValueType* type) {

   switch (type->tag()) {

     case objectTag: return LIR_OprFact::oopConst(NULL);

     case addressTag:

     case intTag:    return LIR_OprFact::intConst(0);

     case floatTag:  return LIR_OprFact::floatConst(0.0);

     case longTag:   return LIR_OprFact::longConst(0);

     case doubleTag: return LIR_OprFact::doubleConst(0.0);

     default:        ShouldNotReachHere(); return LIR_OprFact::intConst(-1);

   }

   return illegalOpr;

 }

 //---------------------------------------------------

 LIR_Address::Scale LIR_Address::scale(BasicType type) {

   int elem_size = type2aelembytes(type);

   switch (elem_size) {

   case 1: return LIR_Address::times_1;

   case 2: return LIR_Address::times_2;

   case 4: return LIR_Address::times_4;

   case 8: return LIR_Address::times_8;

   }

   ShouldNotReachHere();

   return LIR_Address::times_1;

 }

 #ifndef PRODUCT

 void LIR_Address::verify() const {

 #ifdef SPARC

   assert(scale() == times_1, "Scaled addressing mode not available on SPARC and should not be used");

   assert(disp() == 0 || index()->is_illegal(), "can't have both");

 #endif

 #ifdef _LP64

   assert(base()->is_cpu_register(), "wrong base operand");

   assert(index()->is_illegal() || index()->is_double_cpu(), "wrong index operand");

   assert(base()->type() == T_OBJECT || base()->type() == T_LONG,

          "wrong type for addresses");

 #else

   assert(base()->is_single_cpu(), "wrong base operand");

   assert(index()->is_illegal() || index()->is_single_cpu(), "wrong index operand");

   assert(base()->type() == T_OBJECT || base()->type() == T_INT,

          "wrong type for addresses");

 #endif

 }

 #endif

 //---------------------------------------------------

 char LIR_OprDesc::type_char(BasicType t) {

   switch (t) {

     case T_ARRAY:

       t = T_OBJECT;

     case T_BOOLEAN:

     case T_CHAR:

     case T_FLOAT:

     case T_DOUBLE:

     case T_BYTE:

     case T_SHORT:

     case T_INT:

     case T_LONG:

     case T_OBJECT:

     case T_ADDRESS:

     case T_VOID:

       return ::type2char(t);

     case T_ILLEGAL:

       return '?';

     default:

       ShouldNotReachHere();

       return '?';

   }

 }

 #ifndef PRODUCT

 void LIR_OprDesc::validate_type() const {

 #ifdef ASSERT

   if (!is_pointer() && !is_illegal()) {

     switch (as_BasicType(type_field())) {

     case T_LONG:

       assert((kind_field() == cpu_register || kind_field() == stack_value) && size_field() == double_size, "must match");

       break;

     case T_FLOAT:

       assert((kind_field() == fpu_register || kind_field() == stack_value) && size_field() == single_size, "must match");

       break;

     case T_DOUBLE:

       assert((kind_field() == fpu_register || kind_field() == stack_value) && size_field() == double_size, "must match");

       break;

     case T_BOOLEAN:

     case T_CHAR:

     case T_BYTE:

     case T_SHORT:

     case T_INT:

     case T_OBJECT:

     case T_ARRAY:

       assert((kind_field() == cpu_register || kind_field() == stack_value) && size_field() == single_size, "must match");

       break;

     case T_ILLEGAL:

       // XXX TKR also means unknown right now

       // assert(is_illegal(), "must match");

       break;

     default:

       ShouldNotReachHere();

     }

   }

 #endif

 }

 #endif // PRODUCT

 bool LIR_OprDesc::is_oop() const {

   if (is_pointer()) {

     return pointer()->is_oop_pointer();

   } else {

     OprType t= type_field();

     assert(t != unknown_type, "not set");

     return t == object_type;

   }

 }

 void LIR_Op2::verify() const {

 #ifdef ASSERT

   switch (code()) {

     case lir_cmove:

       break;

     default:

       assert(!result_opr()->is_register() || !result_opr()->is_oop_register(),

              "can't produce oops from arith");

   }

   if (TwoOperandLIRForm) {

     switch (code()) {

     case lir_add:

     case lir_sub:

     case lir_mul:

     case lir_mul_strictfp:

     case lir_div:

     case lir_div_strictfp:

     case lir_rem:

     case lir_logic_and:

     case lir_logic_or:

     case lir_logic_xor:

     case lir_shl:

     case lir_shr:

       assert(in_opr1() == result_opr(), "opr1 and result must match");

       assert(in_opr1()->is_valid() && in_opr2()->is_valid(), "must be valid");

       break;

     // special handling for lir_ushr because of write barriers

     case lir_ushr:

       assert(in_opr1() == result_opr() || in_opr2()->is_constant(), "opr1 and result must match or shift count is constant");

       assert(in_opr1()->is_valid() && in_opr2()->is_valid(), "must be valid");

       break;

     }

   }

 #endif

 }

 LIR_OpBranch::LIR_OpBranch(LIR_Condition cond, BasicType type, BlockBegin* block)

   : LIR_Op(lir_branch, LIR_OprFact::illegalOpr, (CodeEmitInfo*)NULL)

   , _cond(cond)

   , _type(type)

   , _label(block->label())

   , _block(block)

   , _ublock(NULL)

   , _stub(NULL) {

 }

 LIR_OpBranch::LIR_OpBranch(LIR_Condition cond, BasicType type, CodeStub* stub) :

   LIR_Op(lir_branch, LIR_OprFact::illegalOpr, (CodeEmitInfo*)NULL)

   , _cond(cond)

   , _type(type)

   , _label(stub->entry())

   , _block(NULL)

   , _ublock(NULL)

   , _stub(stub) {

 }

 LIR_OpBranch::LIR_OpBranch(LIR_Condition cond, BasicType type, BlockBegin* block, BlockBegin* ublock)

   : LIR_Op(lir_cond_float_branch, LIR_OprFact::illegalOpr, (CodeEmitInfo*)NULL)

   , _cond(cond)

   , _type(type)

   , _label(block->label())

   , _block(block)

   , _ublock(ublock)

   , _stub(NULL)

 {

 }

 void LIR_OpBranch::change_block(BlockBegin* b) {

   assert(_block != NULL, "must have old block");

   assert(_block->label() == label(), "must be equal");

   _block = b;

   _label = b->label();

 }

 void LIR_OpBranch::change_ublock(BlockBegin* b) {

   assert(_ublock != NULL, "must have old block");

   _ublock = b;

 }

 void LIR_OpBranch::negate_cond() {

   switch (_cond) {

     case lir_cond_equal:        _cond = lir_cond_notEqual;     break;

     case lir_cond_notEqual:     _cond = lir_cond_equal;        break;

     case lir_cond_less:         _cond = lir_cond_greaterEqual; break;

     case lir_cond_lessEqual:    _cond = lir_cond_greater;      break;

     case lir_cond_greaterEqual: _cond = lir_cond_less;         break;

     case lir_cond_greater:      _cond = lir_cond_lessEqual;    break;

     default: ShouldNotReachHere();

   }

 }

 LIR_OpTypeCheck::LIR_OpTypeCheck(LIR_Code code, LIR_Opr result, LIR_Opr object, ciKlass* klass,

                                  LIR_Opr tmp1, LIR_Opr tmp2, LIR_Opr tmp3,

                                  bool fast_check, CodeEmitInfo* info_for_exception, CodeEmitInfo* info_for_patch,

                                  CodeStub* stub,

                                  ciMethod* profiled_method,

                                  int profiled_bci)

   : LIR_Op(code, result, NULL)

   , _object(object)

   , _array(LIR_OprFact::illegalOpr)

   , _klass(klass)

   , _tmp1(tmp1)

   , _tmp2(tmp2)

   , _tmp3(tmp3)

   , _fast_check(fast_check)

   , _stub(stub)

   , _info_for_patch(info_for_patch)

   , _info_for_exception(info_for_exception)

   , _profiled_method(profiled_method)

   , _profiled_bci(profiled_bci) {

   if (code == lir_checkcast) {

     assert(info_for_exception != NULL, "checkcast throws exceptions");

   } else if (code == lir_instanceof) {

     assert(info_for_exception == NULL, "instanceof throws no exceptions");

   } else {

     ShouldNotReachHere();

   }

 }

 LIR_OpTypeCheck::LIR_OpTypeCheck(LIR_Code code, LIR_Opr object, LIR_Opr array, LIR_Opr tmp1, LIR_Opr tmp2, LIR_Opr tmp3, CodeEmitInfo* info_for_exception, ciMethod* profiled_method, int profiled_bci)

   : LIR_Op(code, LIR_OprFact::illegalOpr, NULL)

   , _object(object)

   , _array(array)

   , _klass(NULL)

   , _tmp1(tmp1)

   , _tmp2(tmp2)

   , _tmp3(tmp3)

   , _fast_check(false)

   , _stub(NULL)

   , _info_for_patch(NULL)

   , _info_for_exception(info_for_exception)

   , _profiled_method(profiled_method)

   , _profiled_bci(profiled_bci) {

   if (code == lir_store_check) {

     _stub = new ArrayStoreExceptionStub(info_for_exception);

     assert(info_for_exception != NULL, "store_check throws exceptions");

   } else {

     ShouldNotReachHere();

   }

 }

 LIR_OpArrayCopy::LIR_OpArrayCopy(LIR_Opr src, LIR_Opr src_pos, LIR_Opr dst, LIR_Opr dst_pos, LIR_Opr length,

                                  LIR_Opr tmp, ciArrayKlass* expected_type, int flags, CodeEmitInfo* info)

   : LIR_Op(lir_arraycopy, LIR_OprFact::illegalOpr, info)

   , _tmp(tmp)

   , _src(src)

   , _src_pos(src_pos)

   , _dst(dst)

   , _dst_pos(dst_pos)

   , _flags(flags)

   , _expected_type(expected_type)

   , _length(length) {

   _stub = new ArrayCopyStub(this);

 }

 //-------------------verify--------------------------

 void LIR_Op1::verify() const {

   switch(code()) {

   case lir_move:

     assert(in_opr()->is_valid() && result_opr()->is_valid(), "must be");

     break;

   case lir_null_check:

     assert(in_opr()->is_register(), "must be");

     break;

   case lir_return:

     assert(in_opr()->is_register() || in_opr()->is_illegal(), "must be");

     break;

   }

 }

 void LIR_OpRTCall::verify() const {

   assert(strcmp(Runtime1::name_for_address(addr()), "<unknown function>") != 0, "unknown function");

 }

 //-------------------visits--------------------------

 // complete rework of LIR instruction visitor.

 // The virtual calls for each instruction type is replaced by a big

 // switch that adds the operands for each instruction

 void LIR_OpVisitState::visit(LIR_Op* op) {

   // copy information from the LIR_Op

   reset();

   set_op(op);

   switch (op->code()) {

 // LIR_Op0

     case lir_word_align:               // result and info always invalid

     case lir_backwardbranch_target:    // result and info always invalid

     case lir_build_frame:              // result and info always invalid

     case lir_fpop_raw:                 // result and info always invalid

     case lir_24bit_FPU:                // result and info always invalid

     case lir_reset_FPU:                // result and info always invalid

     case lir_breakpoint:               // result and info always invalid

     case lir_membar:                   // result and info always invalid

     case lir_membar_acquire:           // result and info always invalid

     case lir_membar_release:           // result and info always invalid

     {

       assert(op->as_Op0() != NULL, "must be");

       assert(op->_info == NULL, "info not used by this instruction");

       assert(op->_result->is_illegal(), "not used");

       break;

     }

     case lir_nop:                      // may have info, result always invalid

     case lir_std_entry:                // may have result, info always invalid

     case lir_osr_entry:                // may have result, info always invalid

     case lir_get_thread:               // may have result, info always invalid

     {

       assert(op->as_Op0() != NULL, "must be");

       if (op->_info != NULL)           do_info(op->_info);

       if (op->_result->is_valid())     do_output(op->_result);

       break;

     }

 // LIR_OpLabel

     case lir_label:                    // result and info always invalid

     {

       assert(op->as_OpLabel() != NULL, "must be");

       assert(op->_info == NULL, "info not used by this instruction");

       assert(op->_result->is_illegal(), "not used");

       break;

     }

 // LIR_Op1

     case lir_fxch:           // input always valid, result and info always invalid

     case lir_fld:            // input always valid, result and info always invalid

     case lir_ffree:          // input always valid, result and info always invalid

     case lir_push:           // input always valid, result and info always invalid

     case lir_pop:            // input always valid, result and info always invalid

     case lir_return:         // input always valid, result and info always invalid

     case lir_leal:           // input and result always valid, info always invalid

     case lir_neg:            // input and result always valid, info always invalid

     case lir_monaddr:        // input and result always valid, info always invalid

     case lir_null_check:     // input and info always valid, result always invalid

     case lir_move:           // input and result always valid, may have info

     case lir_prefetchr:      // input always valid, result and info always invalid

     case lir_prefetchw:      // input always valid, result and info always invalid

     {

       assert(op->as_Op1() != NULL, "must be");

       LIR_Op1* op1 = (LIR_Op1*)op;

       if (op1->_info)                  do_info(op1->_info);

       if (op1->_opr->is_valid())       do_input(op1->_opr);

       if (op1->_result->is_valid())    do_output(op1->_result);

       break;

     }

     case lir_safepoint:

     {

       assert(op->as_Op1() != NULL, "must be");

       LIR_Op1* op1 = (LIR_Op1*)op;

       assert(op1->_info != NULL, "");  do_info(op1->_info);

       if (op1->_opr->is_valid())       do_temp(op1->_opr); // safepoints on SPARC need temporary register

       assert(op1->_result->is_illegal(), "safepoint does not produce value");

       break;

     }

 // LIR_OpConvert;

     case lir_convert:        // input and result always valid, info always invalid

     {

       assert(op->as_OpConvert() != NULL, "must be");

       LIR_OpConvert* opConvert = (LIR_OpConvert*)op;

       assert(opConvert->_info == NULL, "must be");

       if (opConvert->_opr->is_valid())       do_input(opConvert->_opr);

       if (opConvert->_result->is_valid())    do_output(opConvert->_result);

       do_stub(opConvert->_stub);

       break;

     }

 // LIR_OpBranch;

     case lir_branch:                   // may have info, input and result register always invalid

     case lir_cond_float_branch:        // may have info, input and result register always invalid

     {

       assert(op->as_OpBranch() != NULL, "must be");

       LIR_OpBranch* opBranch = (LIR_OpBranch*)op;

       if (opBranch->_info != NULL)     do_info(opBranch->_info);

       assert(opBranch->_result->is_illegal(), "not used");

       if (opBranch->_stub != NULL)     opBranch->stub()->visit(this);

       break;

     }

 // LIR_OpAllocObj

     case lir_alloc_object:

     {

       assert(op->as_OpAllocObj() != NULL, "must be");

       LIR_OpAllocObj* opAllocObj = (LIR_OpAllocObj*)op;

       if (opAllocObj->_info)                     do_info(opAllocObj->_info);

       if (opAllocObj->_opr->is_valid())          do_input(opAllocObj->_opr);

       if (opAllocObj->_tmp1->is_valid())         do_temp(opAllocObj->_tmp1);

       if (opAllocObj->_tmp2->is_valid())         do_temp(opAllocObj->_tmp2);

       if (opAllocObj->_tmp3->is_valid())         do_temp(opAllocObj->_tmp3);

       if (opAllocObj->_tmp4->is_valid())         do_temp(opAllocObj->_tmp4);

       if (opAllocObj->_result->is_valid())       do_output(opAllocObj->_result);

                                                  do_stub(opAllocObj->_stub);

       break;

     }

 // LIR_OpRoundFP;

     case lir_roundfp: {

       assert(op->as_OpRoundFP() != NULL, "must be");

       LIR_OpRoundFP* opRoundFP = (LIR_OpRoundFP*)op;

       assert(op->_info == NULL, "info not used by this instruction");

       assert(opRoundFP->_tmp->is_illegal(), "not used");

       do_input(opRoundFP->_opr);

       do_output(opRoundFP->_result);

       break;

     }

 // LIR_Op2

     case lir_cmp:

     case lir_cmp_l2i:

     case lir_ucmp_fd2i:

     case lir_cmp_fd2i:

     case lir_add:

     case lir_sub:

     case lir_mul:

     case lir_div:

     case lir_rem:

     case lir_sqrt:

     case lir_abs:

     case lir_logic_and:

     case lir_logic_or:

     case lir_logic_xor:

     case lir_shl:

     case lir_shr:

     case lir_ushr:

     {

       assert(op->as_Op2() != NULL, "must be");

       LIR_Op2* op2 = (LIR_Op2*)op;

       if (op2->_info)                     do_info(op2->_info);

       if (op2->_opr1->is_valid())         do_input(op2->_opr1);

       if (op2->_opr2->is_valid())         do_input(op2->_opr2);

       if (op2->_tmp->is_valid())          do_temp(op2->_tmp);

       if (op2->_result->is_valid())       do_output(op2->_result);

       break;

     }

     // special handling for cmove: right input operand must not be equal

     // to the result operand, otherwise the backend fails

     case lir_cmove:

     {

       assert(op->as_Op2() != NULL, "must be");

       LIR_Op2* op2 = (LIR_Op2*)op;

       assert(op2->_info == NULL && op2->_tmp->is_illegal(), "not used");

       assert(op2->_opr1->is_valid() && op2->_opr2->is_valid() && op2->_result->is_valid(), "used");

       do_input(op2->_opr1);

       do_input(op2->_opr2);

       do_temp(op2->_opr2);

       do_output(op2->_result);

       break;

     }

     // vspecial handling for strict operations: register input operands

     // as temp to guarantee that they do not overlap with other

     // registers

     case lir_mul_strictfp:

     case lir_div_strictfp:

     {

       assert(op->as_Op2() != NULL, "must be");

       LIR_Op2* op2 = (LIR_Op2*)op;

       assert(op2->_info == NULL, "not used");

       assert(op2->_opr1->is_valid(), "used");

       assert(op2->_opr2->is_valid(), "used");

       assert(op2->_result->is_valid(), "used");

       do_input(op2->_opr1); do_temp(op2->_opr1);

       do_input(op2->_opr2); do_temp(op2->_opr2);

       if (op2->_tmp->is_valid()) do_temp(op2->_tmp);

       do_output(op2->_result);

       break;

     }

     case lir_throw:

     case lir_unwind: {

       assert(op->as_Op2() != NULL, "must be");

       LIR_Op2* op2 = (LIR_Op2*)op;

       if (op2->_info)                     do_info(op2->_info);

       if (op2->_opr1->is_valid())         do_temp(op2->_opr1);

       if (op2->_opr2->is_valid())         do_input(op2->_opr2); // exception object is input parameter

       assert(op2->_result->is_illegal(), "no result");

       break;

     }

     case lir_tan:

     case lir_sin:

     case lir_cos:

     case lir_log:

     case lir_log10: {

       assert(op->as_Op2() != NULL, "must be");

       LIR_Op2* op2 = (LIR_Op2*)op;

       // On x86 tan/sin/cos need two temporary fpu stack slots and

       // log/log10 need one so handle opr2 and tmp as temp inputs.

       // Register input operand as temp to guarantee that it doesn't

       // overlap with the input.

       assert(op2->_info == NULL, "not used");

       assert(op2->_opr1->is_valid(), "used");

       do_input(op2->_opr1); do_temp(op2->_opr1);

       if (op2->_opr2->is_valid())         do_temp(op2->_opr2);

       if (op2->_tmp->is_valid())          do_temp(op2->_tmp);

       if (op2->_result->is_valid())       do_output(op2->_result);

       break;

     }

 // LIR_Op3

     case lir_idiv:

     case lir_irem: {

       assert(op->as_Op3() != NULL, "must be");

       LIR_Op3* op3= (LIR_Op3*)op;

       if (op3->_info)                     do_info(op3->_info);

       if (op3->_opr1->is_valid())         do_input(op3->_opr1);

       // second operand is input and temp, so ensure that second operand

       // and third operand get not the same register

       if (op3->_opr2->is_valid())         do_input(op3->_opr2);

       if (op3->_opr2->is_valid())         do_temp(op3->_opr2);

       if (op3->_opr3->is_valid())         do_temp(op3->_opr3);

       if (op3->_result->is_valid())       do_output(op3->_result);

       break;

     }

 // LIR_OpJavaCall

     case lir_static_call:

     case lir_optvirtual_call:

     case lir_icvirtual_call:

     case lir_virtual_call: {

       assert(op->as_OpJavaCall() != NULL, "must be");

       LIR_OpJavaCall* opJavaCall = (LIR_OpJavaCall*)op;

       if (opJavaCall->_receiver->is_valid())     do_input(opJavaCall->_receiver);

       // only visit register parameters

       int n = opJavaCall->_arguments->length();

       for (int i = 0; i < n; i++) {

         if (!opJavaCall->_arguments->at(i)->is_pointer()) {

           do_input(*opJavaCall->_arguments->adr_at(i));

         }

       }

       if (opJavaCall->_info)                     do_info(opJavaCall->_info);

       do_call();

       if (opJavaCall->_result->is_valid())       do_output(opJavaCall->_result);

       break;

     }

 // LIR_OpRTCall

     case lir_rtcall: {

       assert(op->as_OpRTCall() != NULL, "must be");

       LIR_OpRTCall* opRTCall = (LIR_OpRTCall*)op;

       // only visit register parameters

       int n = opRTCall->_arguments->length();

       for (int i = 0; i < n; i++) {

         if (!opRTCall->_arguments->at(i)->is_pointer()) {

           do_input(*opRTCall->_arguments->adr_at(i));

         }

       }

       if (opRTCall->_info)                     do_info(opRTCall->_info);

       if (opRTCall->_tmp->is_valid())          do_temp(opRTCall->_tmp);

       do_call();

       if (opRTCall->_result->is_valid())       do_output(opRTCall->_result);

       break;

     }

 // LIR_OpArrayCopy

     case lir_arraycopy: {

       assert(op->as_OpArrayCopy() != NULL, "must be");

       LIR_OpArrayCopy* opArrayCopy = (LIR_OpArrayCopy*)op;

       assert(opArrayCopy->_result->is_illegal(), "unused");

       assert(opArrayCopy->_src->is_valid(), "used");          do_input(opArrayCopy->_src);     do_temp(opArrayCopy->_src);

       assert(opArrayCopy->_src_pos->is_valid(), "used");      do_input(opArrayCopy->_src_pos); do_temp(opArrayCopy->_src_pos);

       assert(opArrayCopy->_dst->is_valid(), "used");          do_input(opArrayCopy->_dst);     do_temp(opArrayCopy->_dst);

       assert(opArrayCopy->_dst_pos->is_valid(), "used");      do_input(opArrayCopy->_dst_pos); do_temp(opArrayCopy->_dst_pos);

       assert(opArrayCopy->_length->is_valid(), "used");       do_input(opArrayCopy->_length);  do_temp(opArrayCopy->_length);

       assert(opArrayCopy->_tmp->is_valid(), "used");          do_temp(opArrayCopy->_tmp);

       if (opArrayCopy->_info)                     do_info(opArrayCopy->_info);

       // the implementation of arraycopy always has a call into the runtime

       do_call();

       break;

     }

 // LIR_OpLock

     case lir_lock:

     case lir_unlock: {

       assert(op->as_OpLock() != NULL, "must be");

       LIR_OpLock* opLock = (LIR_OpLock*)op;

       if (opLock->_info)                          do_info(opLock->_info);

       // TODO: check if these operands really have to be temp

       // (or if input is sufficient). This may have influence on the oop map!

       assert(opLock->_lock->is_valid(), "used");  do_temp(opLock->_lock);

       assert(opLock->_hdr->is_valid(),  "used");  do_temp(opLock->_hdr);

       assert(opLock->_obj->is_valid(),  "used");  do_temp(opLock->_obj);

       if (opLock->_scratch->is_valid())           do_temp(opLock->_scratch);

       assert(opLock->_result->is_illegal(), "unused");

       do_stub(opLock->_stub);

       break;

     }

 // LIR_OpDelay

     case lir_delay_slot: {

       assert(op->as_OpDelay() != NULL, "must be");

       LIR_OpDelay* opDelay = (LIR_OpDelay*)op;

       visit(opDelay->delay_op());

       break;

     }

 // LIR_OpTypeCheck

     case lir_instanceof:

     case lir_checkcast:

     case lir_store_check: {

       assert(op->as_OpTypeCheck() != NULL, "must be");

       LIR_OpTypeCheck* opTypeCheck = (LIR_OpTypeCheck*)op;

       if (opTypeCheck->_info_for_exception)       do_info(opTypeCheck->_info_for_exception);

       if (opTypeCheck->_info_for_patch)           do_info(opTypeCheck->_info_for_patch);

       if (opTypeCheck->_object->is_valid())       do_input(opTypeCheck->_object);

       if (opTypeCheck->_array->is_valid())        do_input(opTypeCheck->_array);

       if (opTypeCheck->_tmp1->is_valid())         do_temp(opTypeCheck->_tmp1);

       if (opTypeCheck->_tmp2->is_valid())         do_temp(opTypeCheck->_tmp2);

       if (opTypeCheck->_tmp3->is_valid())         do_temp(opTypeCheck->_tmp3);

       if (opTypeCheck->_result->is_valid())       do_output(opTypeCheck->_result);

                                                   do_stub(opTypeCheck->_stub);

       break;

     }

 // LIR_OpCompareAndSwap

     case lir_cas_long:

     case lir_cas_obj:

     case lir_cas_int: {

       assert(op->as_OpCompareAndSwap() != NULL, "must be");

       LIR_OpCompareAndSwap* opCompareAndSwap = (LIR_OpCompareAndSwap*)op;

       if (opCompareAndSwap->_info)                    do_info(opCompareAndSwap->_info);

       if (opCompareAndSwap->_addr->is_valid())        do_input(opCompareAndSwap->_addr);

       if (opCompareAndSwap->_cmp_value->is_valid())   do_input(opCompareAndSwap->_cmp_value);

       if (opCompareAndSwap->_new_value->is_valid())   do_input(opCompareAndSwap->_new_value);

       if (opCompareAndSwap->_tmp1->is_valid())        do_temp(opCompareAndSwap->_tmp1);

       if (opCompareAndSwap->_tmp2->is_valid())        do_temp(opCompareAndSwap->_tmp2);

       if (opCompareAndSwap->_result->is_valid())      do_output(opCompareAndSwap->_result);

       break;

     }

 // LIR_OpAllocArray;

     case lir_alloc_array: {

       assert(op->as_OpAllocArray() != NULL, "must be");

       LIR_OpAllocArray* opAllocArray = (LIR_OpAllocArray*)op;

       if (opAllocArray->_info)                        do_info(opAllocArray->_info);

       if (opAllocArray->_klass->is_valid())           do_input(opAllocArray->_klass); do_temp(opAllocArray->_klass);

       if (opAllocArray->_len->is_valid())             do_input(opAllocArray->_len);   do_temp(opAllocArray->_len);

       if (opAllocArray->_tmp1->is_valid())            do_temp(opAllocArray->_tmp1);

       if (opAllocArray->_tmp2->is_valid())            do_temp(opAllocArray->_tmp2);

       if (opAllocArray->_tmp3->is_valid())            do_temp(opAllocArray->_tmp3);

       if (opAllocArray->_tmp4->is_valid())            do_temp(opAllocArray->_tmp4);

       if (opAllocArray->_result->is_valid())          do_output(opAllocArray->_result);

                                                       do_stub(opAllocArray->_stub);

       break;

     }

 // LIR_OpProfileCall:

     case lir_profile_call: {

       assert(op->as_OpProfileCall() != NULL, "must be");

       LIR_OpProfileCall* opProfileCall = (LIR_OpProfileCall*)op;

       if (opProfileCall->_recv->is_valid())              do_temp(opProfileCall->_recv);

       assert(opProfileCall->_mdo->is_valid(), "used");   do_temp(opProfileCall->_mdo);

       assert(opProfileCall->_tmp1->is_valid(), "used");  do_temp(opProfileCall->_tmp1);

       break;

     }

   default:

     ShouldNotReachHere();

   }

 }

 void LIR_OpVisitState::do_stub(CodeStub* stub) {

   if (stub != NULL) {

     stub->visit(this);

   }

 }

 XHandlers* LIR_OpVisitState::all_xhandler() {

   XHandlers* result = NULL;

   int i;

   for (i = 0; i < info_count(); i++) {

     if (info_at(i)->exception_handlers() != NULL) {

       result = info_at(i)->exception_handlers();

       break;

     }

   }

 #ifdef ASSERT

   for (i = 0; i < info_count(); i++) {

     assert(info_at(i)->exception_handlers() == NULL ||

            info_at(i)->exception_handlers() == result,

            "only one xhandler list allowed per LIR-operation");

   }

 #endif

   if (result != NULL) {

     return result;

   } else {

     return new XHandlers();

   }

   return result;

 }

 #ifdef ASSERT

 bool LIR_OpVisitState::no_operands(LIR_Op* op) {

   visit(op);

   return opr_count(inputMode) == 0 &&

          opr_count(outputMode) == 0 &&

          opr_count(tempMode) == 0 &&

          info_count() == 0 &&

          !has_call() &&

          !has_slow_case();

 }

 #endif

 //---------------------------------------------------

 void LIR_OpJavaCall::emit_code(LIR_Assembler* masm) {

   masm->emit_call(this);

 }

 void LIR_OpRTCall::emit_code(LIR_Assembler* masm) {

   masm->emit_rtcall(this);

 }

 void LIR_OpLabel::emit_code(LIR_Assembler* masm) {

   masm->emit_opLabel(this);

 }

 void LIR_OpArrayCopy::emit_code(LIR_Assembler* masm) {

   masm->emit_arraycopy(this);

   masm->emit_code_stub(stub());

 }

 void LIR_Op0::emit_code(LIR_Assembler* masm) {

   masm->emit_op0(this);

 }

 void LIR_Op1::emit_code(LIR_Assembler* masm) {

   masm->emit_op1(this);

 }

 void LIR_OpAllocObj::emit_code(LIR_Assembler* masm) {

   masm->emit_alloc_obj(this);

   masm->emit_code_stub(stub());

 }

 void LIR_OpBranch::emit_code(LIR_Assembler* masm) {

   masm->emit_opBranch(this);

   if (stub()) {

     masm->emit_code_stub(stub());

   }

 }

 void LIR_OpConvert::emit_code(LIR_Assembler* masm) {

   masm->emit_opConvert(this);

   if (stub() != NULL) {

     masm->emit_code_stub(stub());

   }

 }

 void LIR_Op2::emit_code(LIR_Assembler* masm) {

   masm->emit_op2(this);

 }

 void LIR_OpAllocArray::emit_code(LIR_Assembler* masm) {

   masm->emit_alloc_array(this);

   masm->emit_code_stub(stub());

 }

 void LIR_OpTypeCheck::emit_code(LIR_Assembler* masm) {

   masm->emit_opTypeCheck(this);

   if (stub()) {

     masm->emit_code_stub(stub());

   }

 }

 void LIR_OpCompareAndSwap::emit_code(LIR_Assembler* masm) {

   masm->emit_compare_and_swap(this);

 }

 void LIR_Op3::emit_code(LIR_Assembler* masm) {

   masm->emit_op3(this);

 }

 void LIR_OpLock::emit_code(LIR_Assembler* masm) {

   masm->emit_lock(this);

   if (stub()) {

     masm->emit_code_stub(stub());

   }

 }

 void LIR_OpDelay::emit_code(LIR_Assembler* masm) {

   masm->emit_delay(this);

 }

 void LIR_OpProfileCall::emit_code(LIR_Assembler* masm) {

   masm->emit_profile_call(this);

 }

 // LIR_List

 LIR_List::LIR_List(Compilation* compilation, BlockBegin* block)

   : _operations(8)

   , _compilation(compilation)

 #ifndef PRODUCT

   , _block(block)

 #endif

 #ifdef ASSERT

   , _file(NULL)

   , _line(0)

 #endif

 { }

 #ifdef ASSERT

 void LIR_List::set_file_and_line(const char * file, int line) {

   const char * f = strrchr(file, '/');

   if (f == NULL) f = strrchr(file, '\\');

   if (f == NULL) {

     f = file;

   } else {

     f++;

   }

   _file = f;

   _line = line;

 }

 #endif

 void LIR_List::append(LIR_InsertionBuffer* buffer) {

   assert(this == buffer->lir_list(), "wrong lir list");

   const int n = _operations.length();

   if (buffer->number_of_ops() > 0) {

     // increase size of instructions list

     _operations.at_grow(n + buffer->number_of_ops() - 1, NULL);

     // insert ops from buffer into instructions list

     int op_index = buffer->number_of_ops() - 1;

     int ip_index = buffer->number_of_insertion_points() - 1;

     int from_index = n - 1;

     int to_index = _operations.length() - 1;

     for (; ip_index >= 0; ip_index --) {

       int index = buffer->index_at(ip_index);

       // make room after insertion point

       while (index < from_index) {

         _operations.at_put(to_index --, _operations.at(from_index --));

       }

       // insert ops from buffer

       for (int i = buffer->count_at(ip_index); i > 0; i --) {

         _operations.at_put(to_index --, buffer->op_at(op_index --));

       }

     }

   }

   buffer->finish();

 }

 void LIR_List::oop2reg_patch(jobject o, LIR_Opr reg, CodeEmitInfo* info) {

   append(new LIR_Op1(lir_move, LIR_OprFact::oopConst(o),  reg, T_OBJECT, lir_patch_normal, info));

 }

 void LIR_List::load(LIR_Address* addr, LIR_Opr src, CodeEmitInfo* info, LIR_PatchCode patch_code) {

   append(new LIR_Op1(

             lir_move,

             LIR_OprFact::address(addr),

             src,

             addr->type(),

             patch_code,

             info));

 }

 void LIR_List::volatile_load_mem_reg(LIR_Address* address, LIR_Opr dst, CodeEmitInfo* info, LIR_PatchCode patch_code) {

   append(new LIR_Op1(

             lir_move,

             LIR_OprFact::address(address),

             dst,

             address->type(),

             patch_code,

             info, lir_move_volatile));

 }

 void LIR_List::volatile_load_unsafe_reg(LIR_Opr base, LIR_Opr offset, LIR_Opr dst, BasicType type, CodeEmitInfo* info, LIR_PatchCode patch_code) {

   append(new LIR_Op1(

             lir_move,

             LIR_OprFact::address(new LIR_Address(base, offset, type)),

             dst,

             type,

             patch_code,

             info, lir_move_volatile));

 }

 void LIR_List::prefetch(LIR_Address* addr, bool is_store) {

   append(new LIR_Op1(

             is_store ? lir_prefetchw : lir_prefetchr,

             LIR_OprFact::address(addr)));

 }

 void LIR_List::store_mem_int(jint v, LIR_Opr base, int offset_in_bytes, BasicType type, CodeEmitInfo* info, LIR_PatchCode patch_code) {

   append(new LIR_Op1(

             lir_move,

             LIR_OprFact::intConst(v),

             LIR_OprFact::address(new LIR_Address(base, offset_in_bytes, type)),

             type,

             patch_code,

             info));

 }

 void LIR_List::store_mem_oop(jobject o, LIR_Opr base, int offset_in_bytes, BasicType type, CodeEmitInfo* info, LIR_PatchCode patch_code) {

   append(new LIR_Op1(

             lir_move,

             LIR_OprFact::oopConst(o),

             LIR_OprFact::address(new LIR_Address(base, offset_in_bytes, type)),

             type,

             patch_code,

             info));

 }

 void LIR_List::store(LIR_Opr src, LIR_Address* addr, CodeEmitInfo* info, LIR_PatchCode patch_code) {

   append(new LIR_Op1(

             lir_move,

             src,

             LIR_OprFact::address(addr),

             addr->type(),

             patch_code,

             info));

 }

 void LIR_List::volatile_store_mem_reg(LIR_Opr src, LIR_Address* addr, CodeEmitInfo* info, LIR_PatchCode patch_code) {

   append(new LIR_Op1(

             lir_move,

             src,

             LIR_OprFact::address(addr),

             addr->type(),

             patch_code,

             info,

             lir_move_volatile));

 }

 void LIR_List::volatile_store_unsafe_reg(LIR_Opr src, LIR_Opr base, LIR_Opr offset, BasicType type, CodeEmitInfo* info, LIR_PatchCode patch_code) {

   append(new LIR_Op1(

             lir_move,

             src,

             LIR_OprFact::address(new LIR_Address(base, offset, type)),

             type,

             patch_code,

             info, lir_move_volatile));

 }

 void LIR_List::idiv(LIR_Opr left, LIR_Opr right, LIR_Opr res, LIR_Opr tmp, CodeEmitInfo* info) {

   append(new LIR_Op3(

                     lir_idiv,

                     left,

                     right,

                     tmp,

                     res,

                     info));

 }

 void LIR_List::idiv(LIR_Opr left, int right, LIR_Opr res, LIR_Opr tmp, CodeEmitInfo* info) {

   append(new LIR_Op3(

                     lir_idiv,

                     left,

                     LIR_OprFact::intConst(right),

                     tmp,

                     res,

                     info));

 }

 void LIR_List::irem(LIR_Opr left, LIR_Opr right, LIR_Opr res, LIR_Opr tmp, CodeEmitInfo* info) {

   append(new LIR_Op3(

                     lir_irem,

                     left,

                     right,

                     tmp,

                     res,

                     info));

 }

 void LIR_List::irem(LIR_Opr left, int right, LIR_Opr res, LIR_Opr tmp, CodeEmitInfo* info) {

   append(new LIR_Op3(

                     lir_irem,

                     left,

                     LIR_OprFact::intConst(right),

                     tmp,

                     res,

                     info));

 }

 void LIR_List::cmp_mem_int(LIR_Condition condition, LIR_Opr base, int disp, int c, CodeEmitInfo* info) {

   append(new LIR_Op2(

                     lir_cmp,

                     condition,

                     LIR_OprFact::address(new LIR_Address(base, disp, T_INT)),

                     LIR_OprFact::intConst(c),

                     info));

 }

 void LIR_List::cmp_reg_mem(LIR_Condition condition, LIR_Opr reg, LIR_Address* addr, CodeEmitInfo* info) {

   append(new LIR_Op2(

                     lir_cmp,

                     condition,

                     reg,

                     LIR_OprFact::address(addr),

                     info));

 }

 void LIR_List::allocate_object(LIR_Opr dst, LIR_Opr t1, LIR_Opr t2, LIR_Opr t3, LIR_Opr t4,

                                int header_size, int object_size, LIR_Opr klass, bool init_check, CodeStub* stub) {

   append(new LIR_OpAllocObj(

                            klass,

                            dst,

                            t1,

                            t2,

                            t3,

                            t4,

                            header_size,

                            object_size,

                            init_check,

                            stub));

 }

 void LIR_List::allocate_array(LIR_Opr dst, LIR_Opr len, LIR_Opr t1,LIR_Opr t2, LIR_Opr t3,LIR_Opr t4, BasicType type, LIR_Opr klass, CodeStub* stub) {

   append(new LIR_OpAllocArray(

                            klass,

                            len,

                            dst,

                            t1,

                            t2,

                            t3,

                            t4,

                            type,

                            stub));

 }

 void LIR_List::shift_left(LIR_Opr value, LIR_Opr count, LIR_Opr dst, LIR_Opr tmp) {

  append(new LIR_Op2(

                     lir_shl,

                     value,

                     count,

                     dst,

                     tmp));

 }

 void LIR_List::shift_right(LIR_Opr value, LIR_Opr count, LIR_Opr dst, LIR_Opr tmp) {

  append(new LIR_Op2(

                     lir_shr,

                     value,

                     count,

                     dst,

                     tmp));

 }

 void LIR_List::unsigned_shift_right(LIR_Opr value, LIR_Opr count, LIR_Opr dst, LIR_Opr tmp) {

  append(new LIR_Op2(

                     lir_ushr,

                     value,

                     count,

                     dst,

                     tmp));

 }

 void LIR_List::fcmp2int(LIR_Opr left, LIR_Opr right, LIR_Opr dst, bool is_unordered_less) {

   append(new LIR_Op2(is_unordered_less ? lir_ucmp_fd2i : lir_cmp_fd2i,

                      left,

                      right,

                      dst));

 }

 void LIR_List::lock_object(LIR_Opr hdr, LIR_Opr obj, LIR_Opr lock, LIR_Opr scratch, CodeStub* stub, CodeEmitInfo* info) {

   append(new LIR_OpLock(

                     lir_lock,

                     hdr,

                     obj,

                     lock,

                     scratch,

                     stub,

                     info));

 }

 void LIR_List::unlock_object(LIR_Opr hdr, LIR_Opr obj, LIR_Opr lock, CodeStub* stub) {

   append(new LIR_OpLock(

                     lir_unlock,

                     hdr,

                     obj,

                     lock,

                     LIR_OprFact::illegalOpr,

                     stub,

                     NULL));

 }

 void check_LIR() {

   // cannot do the proper checking as PRODUCT and other modes return different results

   // guarantee(sizeof(LIR_OprDesc) == wordSize, "may not have a v-table");

 }

 void LIR_List::checkcast (LIR_Opr result, LIR_Opr object, ciKlass* klass,

                           LIR_Opr tmp1, LIR_Opr tmp2, LIR_Opr tmp3, bool fast_check,

                           CodeEmitInfo* info_for_exception, CodeEmitInfo* info_for_patch, CodeStub* stub,

                           ciMethod* profiled_method, int profiled_bci) {

   append(new LIR_OpTypeCheck(lir_checkcast, result, object, klass,

                              tmp1, tmp2, tmp3, fast_check, info_for_exception, info_for_patch, stub,

                              profiled_method, profiled_bci));

 }

 void LIR_List::instanceof(LIR_Opr result, LIR_Opr object, ciKlass* klass, LIR_Opr tmp1, LIR_Opr tmp2, LIR_Opr tmp3, bool fast_check, CodeEmitInfo* info_for_patch) {

   append(new LIR_OpTypeCheck(lir_instanceof, result, object, klass, tmp1, tmp2, tmp3, fast_check, NULL, info_for_patch, NULL, NULL, 0));

 }

 void LIR_List::store_check(LIR_Opr object, LIR_Opr array, LIR_Opr tmp1, LIR_Opr tmp2, LIR_Opr tmp3, CodeEmitInfo* info_for_exception) {

   append(new LIR_OpTypeCheck(lir_store_check, object, array, tmp1, tmp2, tmp3, info_for_exception, NULL, 0));

 }

 void LIR_List::cas_long(LIR_Opr addr, LIR_Opr cmp_value, LIR_Opr new_value, LIR_Opr t1, LIR_Opr t2) {

   // Compare and swap produces condition code "zero" if contents_of(addr) == cmp_value,

   // implying successful swap of new_value into addr

   append(new LIR_OpCompareAndSwap(lir_cas_long, addr, cmp_value, new_value, t1, t2));

 }

 void LIR_List::cas_obj(LIR_Opr addr, LIR_Opr cmp_value, LIR_Opr new_value, LIR_Opr t1, LIR_Opr t2) {

   // Compare and swap produces condition code "zero" if contents_of(addr) == cmp_value,

   // implying successful swap of new_value into addr

   append(new LIR_OpCompareAndSwap(lir_cas_obj, addr, cmp_value, new_value, t1, t2));

 }

 void LIR_List::cas_int(LIR_Opr addr, LIR_Opr cmp_value, LIR_Opr new_value, LIR_Opr t1, LIR_Opr t2) {

   // Compare and swap produces condition code "zero" if contents_of(addr) == cmp_value,

   // implying successful swap of new_value into addr

   append(new LIR_OpCompareAndSwap(lir_cas_int, addr, cmp_value, new_value, t1, t2));

 }

 #ifdef PRODUCT

 void print_LIR(BlockList* blocks) {

 }

 #else

 // LIR_OprDesc

 void LIR_OprDesc::print() const {

   print(tty);

 }

 void LIR_OprDesc::print(outputStream* out) const {

   if (is_illegal()) {

     return;

   }

   out->print("[");

   if (is_pointer()) {

     pointer()->print_value_on(out);

   } else if (is_single_stack()) {

     out->print("stack:%d", single_stack_ix());

   } else if (is_double_stack()) {

     out->print("dbl_stack:%d",double_stack_ix());

   } else if (is_virtual()) {

     out->print("R%d", vreg_number());

   } else if (is_single_cpu()) {

     out->print(as_register()->name());

   } else if (is_double_cpu()) {

     out->print(as_register_hi()->name());

     out->print(as_register_lo()->name());

 #if defined(X86)

   } else if (is_single_xmm()) {

     out->print(as_xmm_float_reg()->name());

   } else if (is_double_xmm()) {

     out->print(as_xmm_double_reg()->name());

   } else if (is_single_fpu()) {

     out->print("fpu%d", fpu_regnr());

   } else if (is_double_fpu()) {

     out->print("fpu%d", fpu_regnrLo());

 #else

   } else if (is_single_fpu()) {

     out->print(as_float_reg()->name());

   } else if (is_double_fpu()) {

     out->print(as_double_reg()->name());

 #endif

   } else if (is_illegal()) {

     out->print("-");

   } else {

     out->print("Unknown Operand");

   }

   if (!is_illegal()) {

     out->print("|%c", type_char());

   }

   if (is_register() && is_last_use()) {

     out->print("(last_use)");

   }

   out->print("]");

 }

 // LIR_Address

 void LIR_Const::print_value_on(outputStream* out) const {

   switch (type()) {

     case T_INT:    out->print("int:%d",   as_jint());           break;

     case T_LONG:   out->print("lng:%lld", as_jlong());          break;

     case T_FLOAT:  out->print("flt:%f",   as_jfloat());         break;

     case T_DOUBLE: out->print("dbl:%f",   as_jdouble());        break;

     case T_OBJECT: out->print("obj:0x%x", as_jobject());        break;

     default:       out->print("%3d:0x%x",type(), as_jdouble()); break;

   }

 }

 // LIR_Address

 void LIR_Address::print_value_on(outputStream* out) const {

   out->print("Base:"); _base->print(out);

   if (!_index->is_illegal()) {

     out->print(" Index:"); _index->print(out);

     switch (scale()) {

     case times_1: break;

     case times_2: out->print(" * 2"); break;

     case times_4: out->print(" * 4"); break;

     case times_8: out->print(" * 8"); break;

     }

   }

   out->print(" Disp: %d", _disp);

 }

 // debug output of block header without InstructionPrinter

 //       (because phi functions are not necessary for LIR)

 static void print_block(BlockBegin* x) {

   // print block id

   BlockEnd* end = x->end();

   tty->print("B%d ", x->block_id());

   // print flags

   if (x->is_set(BlockBegin::std_entry_flag))               tty->print("std ");

   if (x->is_set(BlockBegin::osr_entry_flag))               tty->print("osr ");

   if (x->is_set(BlockBegin::exception_entry_flag))         tty->print("ex ");

   if (x->is_set(BlockBegin::subroutine_entry_flag))        tty->print("jsr ");

   if (x->is_set(BlockBegin::backward_branch_target_flag))  tty->print("bb ");

   if (x->is_set(BlockBegin::linear_scan_loop_header_flag)) tty->print("lh ");

   if (x->is_set(BlockBegin::linear_scan_loop_end_flag))    tty->print("le ");

   // print block bci range

   tty->print("[%d, %d] ", x->bci(), (end == NULL ? -1 : end->bci()));

   // print predecessors and successors

   if (x->number_of_preds() > 0) {

     tty->print("preds: ");

     for (int i = 0; i < x->number_of_preds(); i ++) {

       tty->print("B%d ", x->pred_at(i)->block_id());

     }

   }

   if (x->number_of_sux() > 0) {

     tty->print("sux: ");

     for (int i = 0; i < x->number_of_sux(); i ++) {

       tty->print("B%d ", x->sux_at(i)->block_id());

     }

   }

   // print exception handlers

   if (x->number_of_exception_handlers() > 0) {

     tty->print("xhandler: ");

     for (int i = 0; i < x->number_of_exception_handlers();  i++) {

       tty->print("B%d ", x->exception_handler_at(i)->block_id());

     }

   }

   tty->cr();

 }

 void print_LIR(BlockList* blocks) {

   tty->print_cr("LIR:");

   int i;

   for (i = 0; i < blocks->length(); i++) {

     BlockBegin* bb = blocks->at(i);

     print_block(bb);

     tty->print("__id_Instruction___________________________________________"); tty->cr();

     bb->lir()->print_instructions();

   }

 }

 void LIR_List::print_instructions() {

   for (int i = 0; i < _operations.length(); i++) {

     _operations.at(i)->print(); tty->cr();

   }

   tty->cr();

 }

 // LIR_Ops printing routines

 // LIR_Op

 void LIR_Op::print_on(outputStream* out) const {

   if (id() != -1 || PrintCFGToFile) {

     out->print("%4d ", id());

   } else {

     out->print("     ");

   }

   out->print(name()); out->print(" ");

   print_instr(out);

   if (info() != NULL) out->print(" [bci:%d]", info()->bci());

 #ifdef ASSERT

   if (Verbose && _file != NULL) {

     out->print(" (%s:%d)", _file, _line);

   }

 #endif

 }

 const char * LIR_Op::name() const {

   const char* s = NULL;

   switch(code()) {

      // LIR_Op0

      case lir_membar:                s = "membar";        break;

      case lir_membar_acquire:        s = "membar_acquire"; break;

      case lir_membar_release:        s = "membar_release"; break;

      case lir_word_align:            s = "word_align";    break;

      case lir_label:                 s = "label";         break;

      case lir_nop:                   s = "nop";           break;

      case lir_backwardbranch_target: s = "backbranch";    break;

      case lir_std_entry:             s = "std_entry";     break;

      case lir_osr_entry:             s = "osr_entry";     break;

      case lir_build_frame:           s = "build_frm";     break;

      case lir_fpop_raw:              s = "fpop_raw";      break;

      case lir_24bit_FPU:             s = "24bit_FPU";     break;

      case lir_reset_FPU:             s = "reset_FPU";     break;

      case lir_breakpoint:            s = "breakpoint";    break;

      case lir_get_thread:            s = "get_thread";    break;

      // LIR_Op1

      case lir_fxch:                  s = "fxch";          break;

      case lir_fld:                   s = "fld";           break;

      case lir_ffree:                 s = "ffree";         break;

      case lir_push:                  s = "push";          break;

      case lir_pop:                   s = "pop";           break;

      case lir_null_check:            s = "null_check";    break;

      case lir_return:                s = "return";        break;

      case lir_safepoint:             s = "safepoint";     break;

      case lir_neg:                   s = "neg";           break;

      case lir_leal:                  s = "leal";          break;

      case lir_branch:                s = "branch";        break;

      case lir_cond_float_branch:     s = "flt_cond_br";   break;

      case lir_move:                  s = "move";          break;

      case lir_roundfp:               s = "roundfp";       break;

      case lir_rtcall:                s = "rtcall";        break;

      case lir_throw:                 s = "throw";         break;

      case lir_unwind:                s = "unwind";        break;

      case lir_convert:               s = "convert";       break;

      case lir_alloc_object:          s = "alloc_obj";     break;

      case lir_monaddr:               s = "mon_addr";      break;

      // LIR_Op2

      case lir_cmp:                   s = "cmp";           break;

      case lir_cmp_l2i:               s = "cmp_l2i";       break;

      case lir_ucmp_fd2i:             s = "ucomp_fd2i";    break;

      case lir_cmp_fd2i:              s = "comp_fd2i";     break;

      case lir_cmove:                 s = "cmove";         break;

      case lir_add:                   s = "add";           break;

      case lir_sub:                   s = "sub";           break;

      case lir_mul:                   s = "mul";           break;

      case lir_mul_strictfp:          s = "mul_strictfp";  break;

      case lir_div:                   s = "div";           break;

      case lir_div_strictfp:          s = "div_strictfp";  break;

      case lir_rem:                   s = "rem";           break;

      case lir_abs:                   s = "abs";           break;

      case lir_sqrt:                  s = "sqrt";          break;

      case lir_sin:                   s = "sin";           break;

      case lir_cos:                   s = "cos";           break;

      case lir_tan:                   s = "tan";           break;

      case lir_log:                   s = "log";           break;

      case lir_log10:                 s = "log10";         break;

      case lir_logic_and:             s = "logic_and";     break;

      case lir_logic_or:              s = "logic_or";      break;

      case lir_logic_xor:             s = "logic_xor";     break;

      case lir_shl:                   s = "shift_left";    break;

      case lir_shr:                   s = "shift_right";   break;

      case lir_ushr:                  s = "ushift_right";  break;

      case lir_alloc_array:           s = "alloc_array";   break;

      // LIR_Op3

      case lir_idiv:                  s = "idiv";          break;

      case lir_irem:                  s = "irem";          break;

      // LIR_OpJavaCall

      case lir_static_call:           s = "static";        break;

      case lir_optvirtual_call:       s = "optvirtual";    break;

      case lir_icvirtual_call:        s = "icvirtual";     break;

      case lir_virtual_call:          s = "virtual";       break;

      // LIR_OpArrayCopy

      case lir_arraycopy:             s = "arraycopy";     break;

      // LIR_OpLock

      case lir_lock:                  s = "lock";          break;

      case lir_unlock:                s = "unlock";        break;

      // LIR_OpDelay

      case lir_delay_slot:            s = "delay";         break;

      // LIR_OpTypeCheck

      case lir_instanceof:            s = "instanceof";    break;

      case lir_checkcast:             s = "checkcast";     break;

      case lir_store_check:           s = "store_check";   break;

      // LIR_OpCompareAndSwap

      case lir_cas_long:              s = "cas_long";      break;

      case lir_cas_obj:               s = "cas_obj";      break;

      case lir_cas_int:               s = "cas_int";      break;

      // LIR_OpProfileCall

      case lir_profile_call:          s = "profile_call";  break;

      case lir_none:                  ShouldNotReachHere();break;

     default:                         s = "illegal_op";    break;

   }

   return s;

 }

 // LIR_OpJavaCall

 void LIR_OpJavaCall::print_instr(outputStream* out) const {

   out->print("call: ");

   out->print("[addr: 0x%x]", address());

   if (receiver()->is_valid()) {

     out->print(" [recv: ");   receiver()->print(out);   out->print("]");

   }

   if (result_opr()->is_valid()) {

     out->print(" [result: "); result_opr()->print(out); out->print("]");

   }

 }

 // LIR_OpLabel

 void LIR_OpLabel::print_instr(outputStream* out) const {

   out->print("[label:0x%x]", _label);

 }

 // LIR_OpArrayCopy

 void LIR_OpArrayCopy::print_instr(outputStream* out) const {

   src()->print(out);     out->print(" ");

   src_pos()->print(out); out->print(" ");

   dst()->print(out);     out->print(" ");

   dst_pos()->print(out); out->print(" ");

   length()->print(out);  out->print(" ");

   tmp()->print(out);     out->print(" ");

 }

 // LIR_OpCompareAndSwap

 void LIR_OpCompareAndSwap::print_instr(outputStream* out) const {

   addr()->print(out);      out->print(" ");

   cmp_value()->print(out); out->print(" ");

   new_value()->print(out); out->print(" ");

   tmp1()->print(out);      out->print(" ");

   tmp2()->print(out);      out->print(" ");

 }

 // LIR_Op0

 void LIR_Op0::print_instr(outputStream* out) const {

   result_opr()->print(out);

 }

 // LIR_Op1

 const char * LIR_Op1::name() const {

   if (code() == lir_move) {

     switch (move_kind()) {

     case lir_move_normal:

       return "move";

     case lir_move_unaligned:

       return "unaligned move";

     case lir_move_volatile:

       return "volatile_move";

     default:

       ShouldNotReachHere();

     return "illegal_op";

     }

   } else {

     return LIR_Op::name();

   }

 }

 void LIR_Op1::print_instr(outputStream* out) const {

   _opr->print(out);         out->print(" ");

   result_opr()->print(out); out->print(" ");

   print_patch_code(out, patch_code());

 }

 // LIR_Op1

 void LIR_OpRTCall::print_instr(outputStream* out) const {

   intx a = (intx)addr();

   out->print(Runtime1::name_for_address(addr()));

   out->print(" ");

   tmp()->print(out);

 }

 void LIR_Op1::print_patch_code(outputStream* out, LIR_PatchCode code) {

   switch(code) {

     case lir_patch_none:                                 break;

     case lir_patch_low:    out->print("[patch_low]");    break;

     case lir_patch_high:   out->print("[patch_high]");   break;

     case lir_patch_normal: out->print("[patch_normal]"); break;

     default: ShouldNotReachHere();

   }

 }

 // LIR_OpBranch

 void LIR_OpBranch::print_instr(outputStream* out) const {

   print_condition(out, cond());             out->print(" ");

   if (block() != NULL) {

     out->print("[B%d] ", block()->block_id());

   } else if (stub() != NULL) {

     out->print("[");

     stub()->print_name(out);

     out->print(": 0x%x]", stub());

     if (stub()->info() != NULL) out->print(" [bci:%d]", stub()->info()->bci());

   } else {

     out->print("[label:0x%x] ", label());

   }

   if (ublock() != NULL) {

     out->print("unordered: [B%d] ", ublock()->block_id());

   }

 }

 void LIR_Op::print_condition(outputStream* out, LIR_Condition cond) {

   switch(cond) {

     case lir_cond_equal:           out->print("[EQ]");      break;

     case lir_cond_notEqual:        out->print("[NE]");      break;

     case lir_cond_less:            out->print("[LT]");      break;

     case lir_cond_lessEqual:       out->print("[LE]");      break;

     case lir_cond_greaterEqual:    out->print("[GE]");      break;

     case lir_cond_greater:         out->print("[GT]");      break;

     case lir_cond_belowEqual:      out->print("[BE]");      break;

     case lir_cond_aboveEqual:      out->print("[AE]");      break;

     case lir_cond_always:          out->print("[AL]");      break;

     default:                       out->print("[%d]",cond); break;

   }

 }

 // LIR_OpConvert

 void LIR_OpConvert::print_instr(outputStream* out) const {

   print_bytecode(out, bytecode());

   in_opr()->print(out);                  out->print(" ");

   result_opr()->print(out);              out->print(" ");

 }

 void LIR_OpConvert::print_bytecode(outputStream* out, Bytecodes::Code code) {

   switch(code) {

     case Bytecodes::_d2f: out->print("[d2f] "); break;

     case Bytecodes::_d2i: out->print("[d2i] "); break;

     case Bytecodes::_d2l: out->print("[d2l] "); break;

     case Bytecodes::_f2d: out->print("[f2d] "); break;

     case Bytecodes::_f2i: out->print("[f2i] "); break;

     case Bytecodes::_f2l: out->print("[f2l] "); break;

     case Bytecodes::_i2b: out->print("[i2b] "); break;

     case Bytecodes::_i2c: out->print("[i2c] "); break;

     case Bytecodes::_i2d: out->print("[i2d] "); break;

     case Bytecodes::_i2f: out->print("[i2f] "); break;

     case Bytecodes::_i2l: out->print("[i2l] "); break;

     case Bytecodes::_i2s: out->print("[i2s] "); break;

     case Bytecodes::_l2i: out->print("[l2i] "); break;

     case Bytecodes::_l2f: out->print("[l2f] "); break;

     case Bytecodes::_l2d: out->print("[l2d] "); break;

     default:

       out->print("[?%d]",code);

     break;

   }

 }

 void LIR_OpAllocObj::print_instr(outputStream* out) const {

   klass()->print(out);                      out->print(" ");

   obj()->print(out);                        out->print(" ");

   tmp1()->print(out);                       out->print(" ");

   tmp2()->print(out);                       out->print(" ");

   tmp3()->print(out);                       out->print(" ");

   tmp4()->print(out);                       out->print(" ");

   out->print("[hdr:%d]", header_size()); out->print(" ");

   out->print("[obj:%d]", object_size()); out->print(" ");

   out->print("[lbl:0x%x]", stub()->entry());

 }

 void LIR_OpRoundFP::print_instr(outputStream* out) const {

   _opr->print(out);         out->print(" ");

   tmp()->print(out);        out->print(" ");

   result_opr()->print(out); out->print(" ");

 }

 // LIR_Op2

 void LIR_Op2::print_instr(outputStream* out) const {

   if (code() == lir_cmove) {

     print_condition(out, condition());         out->print(" ");

   }

   in_opr1()->print(out);    out->print(" ");

   in_opr2()->print(out);    out->print(" ");

   if (tmp_opr()->is_valid()) { tmp_opr()->print(out);    out->print(" "); }

   result_opr()->print(out);

 }

 void LIR_OpAllocArray::print_instr(outputStream* out) const {

   klass()->print(out);                   out->print(" ");

   len()->print(out);                     out->print(" ");

   obj()->print(out);                     out->print(" ");

   tmp1()->print(out);                    out->print(" ");

   tmp2()->print(out);                    out->print(" ");

   tmp3()->print(out);                    out->print(" ");

   tmp4()->print(out);                    out->print(" ");

   out->print("[type:0x%x]", type());     out->print(" ");

   out->print("[label:0x%x]", stub()->entry());

 }

 void LIR_OpTypeCheck::print_instr(outputStream* out) const {

   object()->print(out);                  out->print(" ");

   if (code() == lir_store_check) {

     array()->print(out);                 out->print(" ");

   }

   if (code() != lir_store_check) {

     klass()->print_name_on(out);         out->print(" ");

     if (fast_check())                 out->print("fast_check ");

   }

   tmp1()->print(out);                    out->print(" ");

   tmp2()->print(out);                    out->print(" ");

   tmp3()->print(out);                    out->print(" ");

   result_opr()->print(out);              out->print(" ");

   if (info_for_exception() != NULL) out->print(" [bci:%d]", info_for_exception()->bci());

 }

 // LIR_Op3

 void LIR_Op3::print_instr(outputStream* out) const {

   in_opr1()->print(out);    out->print(" ");

   in_opr2()->print(out);    out->print(" ");

   in_opr3()->print(out);    out->print(" ");

   result_opr()->print(out);

 }

 void LIR_OpLock::print_instr(outputStream* out) const {

   hdr_opr()->print(out);   out->print(" ");

   obj_opr()->print(out);   out->print(" ");

   lock_opr()->print(out);  out->print(" ");

   if (_scratch->is_valid()) {

     _scratch->print(out);  out->print(" ");

   }

   out->print("[lbl:0x%x]", stub()->entry());

 }

 void LIR_OpDelay::print_instr(outputStream* out) const {

   _op->print_on(out);

 }

 // LIR_OpProfileCall

 void LIR_OpProfileCall::print_instr(outputStream* out) const {

   profiled_method()->name()->print_symbol_on(out);

   out->print(".");

   profiled_method()->holder()->name()->print_symbol_on(out);

   out->print(" @ %d ", profiled_bci());

   mdo()->print(out);           out->print(" ");

   recv()->print(out);          out->print(" ");

   tmp1()->print(out);          out->print(" ");

 }

 #endif // PRODUCT

 // Implementation of LIR_InsertionBuffer

 void LIR_InsertionBuffer::append(int index, LIR_Op* op) {

   assert(_index_and_count.length() % 2 == 0, "must have a count for each index");

   int i = number_of_insertion_points() - 1;

   if (i < 0 || index_at(i) < index) {

     append_new(index, 1);

   } else {

     assert(index_at(i) == index, "can append LIR_Ops in ascending order only");

     assert(count_at(i) > 0, "check");

     set_count_at(i, count_at(i) + 1);

   }

   _ops.push(op);

   DEBUG_ONLY(verify());

 }

 #ifdef ASSERT

 void LIR_InsertionBuffer::verify() {

   int sum = 0;

   int prev_idx = -1;

   for (int i = 0; i < number_of_insertion_points(); i++) {

     assert(prev_idx < index_at(i), "index must be ordered ascending");

     sum += count_at(i);

   }

   assert(sum == number_of_ops(), "wrong total sum");

 }

 #endif