matcher.cpp 93.2 KB
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/*
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 * Copyright (c) 1997, 2013, Oracle and/or its affiliates. All rights reserved.
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 * 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.
 *
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 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
 * or visit www.oracle.com if you need additional information or have any
 * questions.
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 *
 */

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#include "precompiled.hpp"
#include "memory/allocation.inline.hpp"
#include "opto/addnode.hpp"
#include "opto/callnode.hpp"
#include "opto/connode.hpp"
#include "opto/idealGraphPrinter.hpp"
#include "opto/matcher.hpp"
#include "opto/memnode.hpp"
#include "opto/opcodes.hpp"
#include "opto/regmask.hpp"
#include "opto/rootnode.hpp"
#include "opto/runtime.hpp"
#include "opto/type.hpp"
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#include "opto/vectornode.hpp"
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#include "runtime/atomic.hpp"
#include "runtime/os.hpp"
#ifdef TARGET_ARCH_MODEL_x86_32
# include "adfiles/ad_x86_32.hpp"
#endif
#ifdef TARGET_ARCH_MODEL_x86_64
# include "adfiles/ad_x86_64.hpp"
#endif
#ifdef TARGET_ARCH_MODEL_sparc
# include "adfiles/ad_sparc.hpp"
#endif
#ifdef TARGET_ARCH_MODEL_zero
# include "adfiles/ad_zero.hpp"
#endif
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#ifdef TARGET_ARCH_MODEL_arm
# include "adfiles/ad_arm.hpp"
#endif
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#ifdef TARGET_ARCH_MODEL_ppc
# include "adfiles/ad_ppc.hpp"
#endif
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OptoReg::Name OptoReg::c_frame_pointer;

const RegMask *Matcher::idealreg2regmask[_last_machine_leaf];
RegMask Matcher::mreg2regmask[_last_Mach_Reg];
RegMask Matcher::STACK_ONLY_mask;
RegMask Matcher::c_frame_ptr_mask;
const uint Matcher::_begin_rematerialize = _BEGIN_REMATERIALIZE;
const uint Matcher::_end_rematerialize   = _END_REMATERIALIZE;

//---------------------------Matcher-------------------------------------------
Matcher::Matcher( Node_List &proj_list ) :
  PhaseTransform( Phase::Ins_Select ),
#ifdef ASSERT
  _old2new_map(C->comp_arena()),
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  _new2old_map(C->comp_arena()),
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#endif
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  _shared_nodes(C->comp_arena()),
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  _reduceOp(reduceOp), _leftOp(leftOp), _rightOp(rightOp),
  _swallowed(swallowed),
  _begin_inst_chain_rule(_BEGIN_INST_CHAIN_RULE),
  _end_inst_chain_rule(_END_INST_CHAIN_RULE),
  _must_clone(must_clone), _proj_list(proj_list),
  _register_save_policy(register_save_policy),
  _c_reg_save_policy(c_reg_save_policy),
  _register_save_type(register_save_type),
  _ruleName(ruleName),
  _allocation_started(false),
  _states_arena(Chunk::medium_size),
  _visited(&_states_arena),
  _shared(&_states_arena),
  _dontcare(&_states_arena) {
  C->set_matcher(this);

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  idealreg2spillmask  [Op_RegI] = NULL;
  idealreg2spillmask  [Op_RegN] = NULL;
  idealreg2spillmask  [Op_RegL] = NULL;
  idealreg2spillmask  [Op_RegF] = NULL;
  idealreg2spillmask  [Op_RegD] = NULL;
  idealreg2spillmask  [Op_RegP] = NULL;
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  idealreg2spillmask  [Op_VecS] = NULL;
  idealreg2spillmask  [Op_VecD] = NULL;
  idealreg2spillmask  [Op_VecX] = NULL;
  idealreg2spillmask  [Op_VecY] = NULL;
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  idealreg2debugmask  [Op_RegI] = NULL;
  idealreg2debugmask  [Op_RegN] = NULL;
  idealreg2debugmask  [Op_RegL] = NULL;
  idealreg2debugmask  [Op_RegF] = NULL;
  idealreg2debugmask  [Op_RegD] = NULL;
  idealreg2debugmask  [Op_RegP] = NULL;
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  idealreg2debugmask  [Op_VecS] = NULL;
  idealreg2debugmask  [Op_VecD] = NULL;
  idealreg2debugmask  [Op_VecX] = NULL;
  idealreg2debugmask  [Op_VecY] = NULL;
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  idealreg2mhdebugmask[Op_RegI] = NULL;
  idealreg2mhdebugmask[Op_RegN] = NULL;
  idealreg2mhdebugmask[Op_RegL] = NULL;
  idealreg2mhdebugmask[Op_RegF] = NULL;
  idealreg2mhdebugmask[Op_RegD] = NULL;
  idealreg2mhdebugmask[Op_RegP] = NULL;
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  idealreg2mhdebugmask[Op_VecS] = NULL;
  idealreg2mhdebugmask[Op_VecD] = NULL;
  idealreg2mhdebugmask[Op_VecX] = NULL;
  idealreg2mhdebugmask[Op_VecY] = NULL;
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  debug_only(_mem_node = NULL;)   // Ideal memory node consumed by mach node
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}

//------------------------------warp_incoming_stk_arg------------------------
// This warps a VMReg into an OptoReg::Name
OptoReg::Name Matcher::warp_incoming_stk_arg( VMReg reg ) {
  OptoReg::Name warped;
  if( reg->is_stack() ) {  // Stack slot argument?
    warped = OptoReg::add(_old_SP, reg->reg2stack() );
    warped = OptoReg::add(warped, C->out_preserve_stack_slots());
    if( warped >= _in_arg_limit )
      _in_arg_limit = OptoReg::add(warped, 1); // Bump max stack slot seen
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    if (!RegMask::can_represent_arg(warped)) {
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      // the compiler cannot represent this method's calling sequence
      C->record_method_not_compilable_all_tiers("unsupported incoming calling sequence");
      return OptoReg::Bad;
    }
    return warped;
  }
  return OptoReg::as_OptoReg(reg);
}

//---------------------------compute_old_SP------------------------------------
OptoReg::Name Compile::compute_old_SP() {
  int fixed    = fixed_slots();
  int preserve = in_preserve_stack_slots();
  return OptoReg::stack2reg(round_to(fixed + preserve, Matcher::stack_alignment_in_slots()));
}



#ifdef ASSERT
void Matcher::verify_new_nodes_only(Node* xroot) {
  // Make sure that the new graph only references new nodes
  ResourceMark rm;
  Unique_Node_List worklist;
  VectorSet visited(Thread::current()->resource_area());
  worklist.push(xroot);
  while (worklist.size() > 0) {
    Node* n = worklist.pop();
    visited <<= n->_idx;
    assert(C->node_arena()->contains(n), "dead node");
    for (uint j = 0; j < n->req(); j++) {
      Node* in = n->in(j);
      if (in != NULL) {
        assert(C->node_arena()->contains(in), "dead node");
        if (!visited.test(in->_idx)) {
          worklist.push(in);
        }
      }
    }
  }
}
#endif


//---------------------------match---------------------------------------------
void Matcher::match( ) {
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  if( MaxLabelRootDepth < 100 ) { // Too small?
    assert(false, "invalid MaxLabelRootDepth, increase it to 100 minimum");
    MaxLabelRootDepth = 100;
  }
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  // One-time initialization of some register masks.
  init_spill_mask( C->root()->in(1) );
  _return_addr_mask = return_addr();
#ifdef _LP64
  // Pointers take 2 slots in 64-bit land
  _return_addr_mask.Insert(OptoReg::add(return_addr(),1));
#endif

  // Map a Java-signature return type into return register-value
  // machine registers for 0, 1 and 2 returned values.
  const TypeTuple *range = C->tf()->range();
  if( range->cnt() > TypeFunc::Parms ) { // If not a void function
    // Get ideal-register return type
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    int ireg = range->field_at(TypeFunc::Parms)->ideal_reg();
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    // Get machine return register
    uint sop = C->start()->Opcode();
    OptoRegPair regs = return_value(ireg, false);

    // And mask for same
    _return_value_mask = RegMask(regs.first());
    if( OptoReg::is_valid(regs.second()) )
      _return_value_mask.Insert(regs.second());
  }

  // ---------------
  // Frame Layout

  // Need the method signature to determine the incoming argument types,
  // because the types determine which registers the incoming arguments are
  // in, and this affects the matched code.
  const TypeTuple *domain = C->tf()->domain();
  uint             argcnt = domain->cnt() - TypeFunc::Parms;
  BasicType *sig_bt        = NEW_RESOURCE_ARRAY( BasicType, argcnt );
  VMRegPair *vm_parm_regs  = NEW_RESOURCE_ARRAY( VMRegPair, argcnt );
  _parm_regs               = NEW_RESOURCE_ARRAY( OptoRegPair, argcnt );
  _calling_convention_mask = NEW_RESOURCE_ARRAY( RegMask, argcnt );
  uint i;
  for( i = 0; i<argcnt; i++ ) {
    sig_bt[i] = domain->field_at(i+TypeFunc::Parms)->basic_type();
  }

  // Pass array of ideal registers and length to USER code (from the AD file)
  // that will convert this to an array of register numbers.
  const StartNode *start = C->start();
  start->calling_convention( sig_bt, vm_parm_regs, argcnt );
#ifdef ASSERT
  // Sanity check users' calling convention.  Real handy while trying to
  // get the initial port correct.
  { for (uint i = 0; i<argcnt; i++) {
      if( !vm_parm_regs[i].first()->is_valid() && !vm_parm_regs[i].second()->is_valid() ) {
        assert(domain->field_at(i+TypeFunc::Parms)==Type::HALF, "only allowed on halve" );
        _parm_regs[i].set_bad();
        continue;
      }
      VMReg parm_reg = vm_parm_regs[i].first();
      assert(parm_reg->is_valid(), "invalid arg?");
      if (parm_reg->is_reg()) {
        OptoReg::Name opto_parm_reg = OptoReg::as_OptoReg(parm_reg);
        assert(can_be_java_arg(opto_parm_reg) ||
               C->stub_function() == CAST_FROM_FN_PTR(address, OptoRuntime::rethrow_C) ||
               opto_parm_reg == inline_cache_reg(),
               "parameters in register must be preserved by runtime stubs");
      }
      for (uint j = 0; j < i; j++) {
        assert(parm_reg != vm_parm_regs[j].first(),
               "calling conv. must produce distinct regs");
      }
    }
  }
#endif

  // Do some initial frame layout.

  // Compute the old incoming SP (may be called FP) as
  //   OptoReg::stack0() + locks + in_preserve_stack_slots + pad2.
  _old_SP = C->compute_old_SP();
  assert( is_even(_old_SP), "must be even" );

  // Compute highest incoming stack argument as
  //   _old_SP + out_preserve_stack_slots + incoming argument size.
  _in_arg_limit = OptoReg::add(_old_SP, C->out_preserve_stack_slots());
  assert( is_even(_in_arg_limit), "out_preserve must be even" );
  for( i = 0; i < argcnt; i++ ) {
    // Permit args to have no register
    _calling_convention_mask[i].Clear();
    if( !vm_parm_regs[i].first()->is_valid() && !vm_parm_regs[i].second()->is_valid() ) {
      continue;
    }
    // calling_convention returns stack arguments as a count of
    // slots beyond OptoReg::stack0()/VMRegImpl::stack0.  We need to convert this to
    // the allocators point of view, taking into account all the
    // preserve area, locks & pad2.

    OptoReg::Name reg1 = warp_incoming_stk_arg(vm_parm_regs[i].first());
    if( OptoReg::is_valid(reg1))
      _calling_convention_mask[i].Insert(reg1);

    OptoReg::Name reg2 = warp_incoming_stk_arg(vm_parm_regs[i].second());
    if( OptoReg::is_valid(reg2))
      _calling_convention_mask[i].Insert(reg2);

    // Saved biased stack-slot register number
    _parm_regs[i].set_pair(reg2, reg1);
  }

  // Finally, make sure the incoming arguments take up an even number of
  // words, in case the arguments or locals need to contain doubleword stack
  // slots.  The rest of the system assumes that stack slot pairs (in
  // particular, in the spill area) which look aligned will in fact be
  // aligned relative to the stack pointer in the target machine.  Double
  // stack slots will always be allocated aligned.
  _new_SP = OptoReg::Name(round_to(_in_arg_limit, RegMask::SlotsPerLong));

  // Compute highest outgoing stack argument as
  //   _new_SP + out_preserve_stack_slots + max(outgoing argument size).
  _out_arg_limit = OptoReg::add(_new_SP, C->out_preserve_stack_slots());
  assert( is_even(_out_arg_limit), "out_preserve must be even" );

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  if (!RegMask::can_represent_arg(OptoReg::add(_out_arg_limit,-1))) {
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    // the compiler cannot represent this method's calling sequence
    C->record_method_not_compilable("must be able to represent all call arguments in reg mask");
  }

  if (C->failing())  return;  // bailed out on incoming arg failure

  // ---------------
  // Collect roots of matcher trees.  Every node for which
  // _shared[_idx] is cleared is guaranteed to not be shared, and thus
  // can be a valid interior of some tree.
  find_shared( C->root() );
  find_shared( C->top() );

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  C->print_method(PHASE_BEFORE_MATCHING);
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  // Create new ideal node ConP #NULL even if it does exist in old space
  // to avoid false sharing if the corresponding mach node is not used.
  // The corresponding mach node is only used in rare cases for derived
  // pointers.
  Node* new_ideal_null = ConNode::make(C, TypePtr::NULL_PTR);

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  // Swap out to old-space; emptying new-space
  Arena *old = C->node_arena()->move_contents(C->old_arena());

  // Save debug and profile information for nodes in old space:
  _old_node_note_array = C->node_note_array();
  if (_old_node_note_array != NULL) {
    C->set_node_note_array(new(C->comp_arena()) GrowableArray<Node_Notes*>
                           (C->comp_arena(), _old_node_note_array->length(),
                            0, NULL));
  }

  // Pre-size the new_node table to avoid the need for range checks.
  grow_new_node_array(C->unique());

  // Reset node counter so MachNodes start with _idx at 0
  int nodes = C->unique(); // save value
  C->set_unique(0);
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  C->reset_dead_node_list();
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  // Recursively match trees from old space into new space.
  // Correct leaves of new-space Nodes; they point to old-space.
  _visited.Clear();             // Clear visit bits for xform call
  C->set_cached_top_node(xform( C->top(), nodes ));
  if (!C->failing()) {
    Node* xroot =        xform( C->root(), 1 );
    if (xroot == NULL) {
      Matcher::soft_match_failure();  // recursive matching process failed
      C->record_method_not_compilable("instruction match failed");
    } else {
      // During matching shared constants were attached to C->root()
      // because xroot wasn't available yet, so transfer the uses to
      // the xroot.
      for( DUIterator_Fast jmax, j = C->root()->fast_outs(jmax); j < jmax; j++ ) {
        Node* n = C->root()->fast_out(j);
        if (C->node_arena()->contains(n)) {
          assert(n->in(0) == C->root(), "should be control user");
          n->set_req(0, xroot);
          --j;
          --jmax;
        }
      }

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      // Generate new mach node for ConP #NULL
      assert(new_ideal_null != NULL, "sanity");
      _mach_null = match_tree(new_ideal_null);
      // Don't set control, it will confuse GCM since there are no uses.
      // The control will be set when this node is used first time
      // in find_base_for_derived().
      assert(_mach_null != NULL, "");

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      C->set_root(xroot->is_Root() ? xroot->as_Root() : NULL);
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#ifdef ASSERT
      verify_new_nodes_only(xroot);
#endif
    }
  }
  if (C->top() == NULL || C->root() == NULL) {
    C->record_method_not_compilable("graph lost"); // %%% cannot happen?
  }
  if (C->failing()) {
    // delete old;
    old->destruct_contents();
    return;
  }
  assert( C->top(), "" );
  assert( C->root(), "" );
  validate_null_checks();

  // Now smoke old-space
  NOT_DEBUG( old->destruct_contents() );

  // ------------------------
  // Set up save-on-entry registers
  Fixup_Save_On_Entry( );
}


//------------------------------Fixup_Save_On_Entry----------------------------
// The stated purpose of this routine is to take care of save-on-entry
// registers.  However, the overall goal of the Match phase is to convert into
// machine-specific instructions which have RegMasks to guide allocation.
// So what this procedure really does is put a valid RegMask on each input
// to the machine-specific variations of all Return, TailCall and Halt
// instructions.  It also adds edgs to define the save-on-entry values (and of
// course gives them a mask).

static RegMask *init_input_masks( uint size, RegMask &ret_adr, RegMask &fp ) {
  RegMask *rms = NEW_RESOURCE_ARRAY( RegMask, size );
  // Do all the pre-defined register masks
  rms[TypeFunc::Control  ] = RegMask::Empty;
  rms[TypeFunc::I_O      ] = RegMask::Empty;
  rms[TypeFunc::Memory   ] = RegMask::Empty;
  rms[TypeFunc::ReturnAdr] = ret_adr;
  rms[TypeFunc::FramePtr ] = fp;
  return rms;
}

//---------------------------init_first_stack_mask-----------------------------
// Create the initial stack mask used by values spilling to the stack.
// Disallow any debug info in outgoing argument areas by setting the
// initial mask accordingly.
void Matcher::init_first_stack_mask() {

  // Allocate storage for spill masks as masks for the appropriate load type.
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  RegMask *rms = (RegMask*)C->comp_arena()->Amalloc_D(sizeof(RegMask) * (3*6+4));
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  idealreg2spillmask  [Op_RegN] = &rms[0];
  idealreg2spillmask  [Op_RegI] = &rms[1];
  idealreg2spillmask  [Op_RegL] = &rms[2];
  idealreg2spillmask  [Op_RegF] = &rms[3];
  idealreg2spillmask  [Op_RegD] = &rms[4];
  idealreg2spillmask  [Op_RegP] = &rms[5];

  idealreg2debugmask  [Op_RegN] = &rms[6];
  idealreg2debugmask  [Op_RegI] = &rms[7];
  idealreg2debugmask  [Op_RegL] = &rms[8];
  idealreg2debugmask  [Op_RegF] = &rms[9];
  idealreg2debugmask  [Op_RegD] = &rms[10];
  idealreg2debugmask  [Op_RegP] = &rms[11];

  idealreg2mhdebugmask[Op_RegN] = &rms[12];
  idealreg2mhdebugmask[Op_RegI] = &rms[13];
  idealreg2mhdebugmask[Op_RegL] = &rms[14];
  idealreg2mhdebugmask[Op_RegF] = &rms[15];
  idealreg2mhdebugmask[Op_RegD] = &rms[16];
  idealreg2mhdebugmask[Op_RegP] = &rms[17];
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  idealreg2spillmask  [Op_VecS] = &rms[18];
  idealreg2spillmask  [Op_VecD] = &rms[19];
  idealreg2spillmask  [Op_VecX] = &rms[20];
  idealreg2spillmask  [Op_VecY] = &rms[21];

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  OptoReg::Name i;

  // At first, start with the empty mask
  C->FIRST_STACK_mask().Clear();

  // Add in the incoming argument area
  OptoReg::Name init = OptoReg::add(_old_SP, C->out_preserve_stack_slots());
  for (i = init; i < _in_arg_limit; i = OptoReg::add(i,1))
    C->FIRST_STACK_mask().Insert(i);

  // Add in all bits past the outgoing argument area
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  guarantee(RegMask::can_represent_arg(OptoReg::add(_out_arg_limit,-1)),
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            "must be able to represent all call arguments in reg mask");
  init = _out_arg_limit;
  for (i = init; RegMask::can_represent(i); i = OptoReg::add(i,1))
    C->FIRST_STACK_mask().Insert(i);

  // Finally, set the "infinite stack" bit.
  C->FIRST_STACK_mask().set_AllStack();

  // Make spill masks.  Registers for their class, plus FIRST_STACK_mask.
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  RegMask aligned_stack_mask = C->FIRST_STACK_mask();
  // Keep spill masks aligned.
  aligned_stack_mask.clear_to_pairs();
  assert(aligned_stack_mask.is_AllStack(), "should be infinite stack");

  *idealreg2spillmask[Op_RegP] = *idealreg2regmask[Op_RegP];
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#ifdef _LP64
  *idealreg2spillmask[Op_RegN] = *idealreg2regmask[Op_RegN];
   idealreg2spillmask[Op_RegN]->OR(C->FIRST_STACK_mask());
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   idealreg2spillmask[Op_RegP]->OR(aligned_stack_mask);
#else
   idealreg2spillmask[Op_RegP]->OR(C->FIRST_STACK_mask());
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#endif
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  *idealreg2spillmask[Op_RegI] = *idealreg2regmask[Op_RegI];
   idealreg2spillmask[Op_RegI]->OR(C->FIRST_STACK_mask());
  *idealreg2spillmask[Op_RegL] = *idealreg2regmask[Op_RegL];
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   idealreg2spillmask[Op_RegL]->OR(aligned_stack_mask);
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  *idealreg2spillmask[Op_RegF] = *idealreg2regmask[Op_RegF];
   idealreg2spillmask[Op_RegF]->OR(C->FIRST_STACK_mask());
  *idealreg2spillmask[Op_RegD] = *idealreg2regmask[Op_RegD];
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   idealreg2spillmask[Op_RegD]->OR(aligned_stack_mask);
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  if (Matcher::vector_size_supported(T_BYTE,4)) {
    *idealreg2spillmask[Op_VecS] = *idealreg2regmask[Op_VecS];
     idealreg2spillmask[Op_VecS]->OR(C->FIRST_STACK_mask());
  }
  if (Matcher::vector_size_supported(T_FLOAT,2)) {
    *idealreg2spillmask[Op_VecD] = *idealreg2regmask[Op_VecD];
     idealreg2spillmask[Op_VecD]->OR(aligned_stack_mask);
  }
  if (Matcher::vector_size_supported(T_FLOAT,4)) {
     aligned_stack_mask.clear_to_sets(RegMask::SlotsPerVecX);
     assert(aligned_stack_mask.is_AllStack(), "should be infinite stack");
    *idealreg2spillmask[Op_VecX] = *idealreg2regmask[Op_VecX];
     idealreg2spillmask[Op_VecX]->OR(aligned_stack_mask);
  }
  if (Matcher::vector_size_supported(T_FLOAT,8)) {
     aligned_stack_mask.clear_to_sets(RegMask::SlotsPerVecY);
     assert(aligned_stack_mask.is_AllStack(), "should be infinite stack");
    *idealreg2spillmask[Op_VecY] = *idealreg2regmask[Op_VecY];
     idealreg2spillmask[Op_VecY]->OR(aligned_stack_mask);
  }
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   if (UseFPUForSpilling) {
     // This mask logic assumes that the spill operations are
     // symmetric and that the registers involved are the same size.
     // On sparc for instance we may have to use 64 bit moves will
     // kill 2 registers when used with F0-F31.
     idealreg2spillmask[Op_RegI]->OR(*idealreg2regmask[Op_RegF]);
     idealreg2spillmask[Op_RegF]->OR(*idealreg2regmask[Op_RegI]);
#ifdef _LP64
     idealreg2spillmask[Op_RegN]->OR(*idealreg2regmask[Op_RegF]);
     idealreg2spillmask[Op_RegL]->OR(*idealreg2regmask[Op_RegD]);
     idealreg2spillmask[Op_RegD]->OR(*idealreg2regmask[Op_RegL]);
     idealreg2spillmask[Op_RegP]->OR(*idealreg2regmask[Op_RegD]);
#else
     idealreg2spillmask[Op_RegP]->OR(*idealreg2regmask[Op_RegF]);
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#ifdef ARM
     // ARM has support for moving 64bit values between a pair of
     // integer registers and a double register
     idealreg2spillmask[Op_RegL]->OR(*idealreg2regmask[Op_RegD]);
     idealreg2spillmask[Op_RegD]->OR(*idealreg2regmask[Op_RegL]);
#endif
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#endif
   }

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  // Make up debug masks.  Any spill slot plus callee-save registers.
  // Caller-save registers are assumed to be trashable by the various
  // inline-cache fixup routines.
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  *idealreg2debugmask  [Op_RegN]= *idealreg2spillmask[Op_RegN];
  *idealreg2debugmask  [Op_RegI]= *idealreg2spillmask[Op_RegI];
  *idealreg2debugmask  [Op_RegL]= *idealreg2spillmask[Op_RegL];
  *idealreg2debugmask  [Op_RegF]= *idealreg2spillmask[Op_RegF];
  *idealreg2debugmask  [Op_RegD]= *idealreg2spillmask[Op_RegD];
  *idealreg2debugmask  [Op_RegP]= *idealreg2spillmask[Op_RegP];

  *idealreg2mhdebugmask[Op_RegN]= *idealreg2spillmask[Op_RegN];
  *idealreg2mhdebugmask[Op_RegI]= *idealreg2spillmask[Op_RegI];
  *idealreg2mhdebugmask[Op_RegL]= *idealreg2spillmask[Op_RegL];
  *idealreg2mhdebugmask[Op_RegF]= *idealreg2spillmask[Op_RegF];
  *idealreg2mhdebugmask[Op_RegD]= *idealreg2spillmask[Op_RegD];
  *idealreg2mhdebugmask[Op_RegP]= *idealreg2spillmask[Op_RegP];
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  // Prevent stub compilations from attempting to reference
  // callee-saved registers from debug info
  bool exclude_soe = !Compile::current()->is_method_compilation();

  for( i=OptoReg::Name(0); i<OptoReg::Name(_last_Mach_Reg); i = OptoReg::add(i,1) ) {
    // registers the caller has to save do not work
    if( _register_save_policy[i] == 'C' ||
        _register_save_policy[i] == 'A' ||
        (_register_save_policy[i] == 'E' && exclude_soe) ) {
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      idealreg2debugmask  [Op_RegN]->Remove(i);
      idealreg2debugmask  [Op_RegI]->Remove(i); // Exclude save-on-call
      idealreg2debugmask  [Op_RegL]->Remove(i); // registers from debug
      idealreg2debugmask  [Op_RegF]->Remove(i); // masks
      idealreg2debugmask  [Op_RegD]->Remove(i);
      idealreg2debugmask  [Op_RegP]->Remove(i);

      idealreg2mhdebugmask[Op_RegN]->Remove(i);
      idealreg2mhdebugmask[Op_RegI]->Remove(i);
      idealreg2mhdebugmask[Op_RegL]->Remove(i);
      idealreg2mhdebugmask[Op_RegF]->Remove(i);
      idealreg2mhdebugmask[Op_RegD]->Remove(i);
      idealreg2mhdebugmask[Op_RegP]->Remove(i);
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    }
  }
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  // Subtract the register we use to save the SP for MethodHandle
  // invokes to from the debug mask.
  const RegMask save_mask = method_handle_invoke_SP_save_mask();
  idealreg2mhdebugmask[Op_RegN]->SUBTRACT(save_mask);
  idealreg2mhdebugmask[Op_RegI]->SUBTRACT(save_mask);
  idealreg2mhdebugmask[Op_RegL]->SUBTRACT(save_mask);
  idealreg2mhdebugmask[Op_RegF]->SUBTRACT(save_mask);
  idealreg2mhdebugmask[Op_RegD]->SUBTRACT(save_mask);
  idealreg2mhdebugmask[Op_RegP]->SUBTRACT(save_mask);
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}

//---------------------------is_save_on_entry----------------------------------
bool Matcher::is_save_on_entry( int reg ) {
  return
    _register_save_policy[reg] == 'E' ||
    _register_save_policy[reg] == 'A' || // Save-on-entry register?
    // Also save argument registers in the trampolining stubs
    (C->save_argument_registers() && is_spillable_arg(reg));
}

//---------------------------Fixup_Save_On_Entry-------------------------------
void Matcher::Fixup_Save_On_Entry( ) {
  init_first_stack_mask();

  Node *root = C->root();       // Short name for root
  // Count number of save-on-entry registers.
  uint soe_cnt = number_of_saved_registers();
  uint i;

  // Find the procedure Start Node
  StartNode *start = C->start();
  assert( start, "Expect a start node" );

  // Save argument registers in the trampolining stubs
  if( C->save_argument_registers() )
    for( i = 0; i < _last_Mach_Reg; i++ )
      if( is_spillable_arg(i) )
        soe_cnt++;

  // Input RegMask array shared by all Returns.
  // The type for doubles and longs has a count of 2, but
  // there is only 1 returned value
  uint ret_edge_cnt = TypeFunc::Parms + ((C->tf()->range()->cnt() == TypeFunc::Parms) ? 0 : 1);
  RegMask *ret_rms  = init_input_masks( ret_edge_cnt + soe_cnt, _return_addr_mask, c_frame_ptr_mask );
  // Returns have 0 or 1 returned values depending on call signature.
  // Return register is specified by return_value in the AD file.
  if (ret_edge_cnt > TypeFunc::Parms)
    ret_rms[TypeFunc::Parms+0] = _return_value_mask;

  // Input RegMask array shared by all Rethrows.
  uint reth_edge_cnt = TypeFunc::Parms+1;
  RegMask *reth_rms  = init_input_masks( reth_edge_cnt + soe_cnt, _return_addr_mask, c_frame_ptr_mask );
  // Rethrow takes exception oop only, but in the argument 0 slot.
  reth_rms[TypeFunc::Parms] = mreg2regmask[find_receiver(false)];
#ifdef _LP64
  // Need two slots for ptrs in 64-bit land
  reth_rms[TypeFunc::Parms].Insert(OptoReg::add(OptoReg::Name(find_receiver(false)),1));
#endif

  // Input RegMask array shared by all TailCalls
  uint tail_call_edge_cnt = TypeFunc::Parms+2;
  RegMask *tail_call_rms = init_input_masks( tail_call_edge_cnt + soe_cnt, _return_addr_mask, c_frame_ptr_mask );

  // Input RegMask array shared by all TailJumps
  uint tail_jump_edge_cnt = TypeFunc::Parms+2;
  RegMask *tail_jump_rms = init_input_masks( tail_jump_edge_cnt + soe_cnt, _return_addr_mask, c_frame_ptr_mask );

  // TailCalls have 2 returned values (target & moop), whose masks come
  // from the usual MachNode/MachOper mechanism.  Find a sample
  // TailCall to extract these masks and put the correct masks into
  // the tail_call_rms array.
  for( i=1; i < root->req(); i++ ) {
    MachReturnNode *m = root->in(i)->as_MachReturn();
    if( m->ideal_Opcode() == Op_TailCall ) {
      tail_call_rms[TypeFunc::Parms+0] = m->MachNode::in_RegMask(TypeFunc::Parms+0);
      tail_call_rms[TypeFunc::Parms+1] = m->MachNode::in_RegMask(TypeFunc::Parms+1);
      break;
    }
  }

  // TailJumps have 2 returned values (target & ex_oop), whose masks come
  // from the usual MachNode/MachOper mechanism.  Find a sample
  // TailJump to extract these masks and put the correct masks into
  // the tail_jump_rms array.
  for( i=1; i < root->req(); i++ ) {
    MachReturnNode *m = root->in(i)->as_MachReturn();
    if( m->ideal_Opcode() == Op_TailJump ) {
      tail_jump_rms[TypeFunc::Parms+0] = m->MachNode::in_RegMask(TypeFunc::Parms+0);
      tail_jump_rms[TypeFunc::Parms+1] = m->MachNode::in_RegMask(TypeFunc::Parms+1);
      break;
    }
  }

  // Input RegMask array shared by all Halts
  uint halt_edge_cnt = TypeFunc::Parms;
  RegMask *halt_rms = init_input_masks( halt_edge_cnt + soe_cnt, _return_addr_mask, c_frame_ptr_mask );

  // Capture the return input masks into each exit flavor
  for( i=1; i < root->req(); i++ ) {
    MachReturnNode *exit = root->in(i)->as_MachReturn();
    switch( exit->ideal_Opcode() ) {
      case Op_Return   : exit->_in_rms = ret_rms;  break;
      case Op_Rethrow  : exit->_in_rms = reth_rms; break;
      case Op_TailCall : exit->_in_rms = tail_call_rms; break;
      case Op_TailJump : exit->_in_rms = tail_jump_rms; break;
      case Op_Halt     : exit->_in_rms = halt_rms; break;
      default          : ShouldNotReachHere();
    }
  }

  // Next unused projection number from Start.
  int proj_cnt = C->tf()->domain()->cnt();

  // Do all the save-on-entry registers.  Make projections from Start for
  // them, and give them a use at the exit points.  To the allocator, they
  // look like incoming register arguments.
  for( i = 0; i < _last_Mach_Reg; i++ ) {
    if( is_save_on_entry(i) ) {

      // Add the save-on-entry to the mask array
      ret_rms      [      ret_edge_cnt] = mreg2regmask[i];
      reth_rms     [     reth_edge_cnt] = mreg2regmask[i];
      tail_call_rms[tail_call_edge_cnt] = mreg2regmask[i];
      tail_jump_rms[tail_jump_edge_cnt] = mreg2regmask[i];
      // Halts need the SOE registers, but only in the stack as debug info.
      // A just-prior uncommon-trap or deoptimization will use the SOE regs.
      halt_rms     [     halt_edge_cnt] = *idealreg2spillmask[_register_save_type[i]];

      Node *mproj;

      // Is this a RegF low half of a RegD?  Double up 2 adjacent RegF's
      // into a single RegD.
      if( (i&1) == 0 &&
          _register_save_type[i  ] == Op_RegF &&
          _register_save_type[i+1] == Op_RegF &&
          is_save_on_entry(i+1) ) {
        // Add other bit for double
        ret_rms      [      ret_edge_cnt].Insert(OptoReg::Name(i+1));
        reth_rms     [     reth_edge_cnt].Insert(OptoReg::Name(i+1));
        tail_call_rms[tail_call_edge_cnt].Insert(OptoReg::Name(i+1));
        tail_jump_rms[tail_jump_edge_cnt].Insert(OptoReg::Name(i+1));
        halt_rms     [     halt_edge_cnt].Insert(OptoReg::Name(i+1));
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        mproj = new (C) MachProjNode( start, proj_cnt, ret_rms[ret_edge_cnt], Op_RegD );
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        proj_cnt += 2;          // Skip 2 for doubles
      }
      else if( (i&1) == 1 &&    // Else check for high half of double
               _register_save_type[i-1] == Op_RegF &&
               _register_save_type[i  ] == Op_RegF &&
               is_save_on_entry(i-1) ) {
        ret_rms      [      ret_edge_cnt] = RegMask::Empty;
        reth_rms     [     reth_edge_cnt] = RegMask::Empty;
        tail_call_rms[tail_call_edge_cnt] = RegMask::Empty;
        tail_jump_rms[tail_jump_edge_cnt] = RegMask::Empty;
        halt_rms     [     halt_edge_cnt] = RegMask::Empty;
        mproj = C->top();
      }
      // Is this a RegI low half of a RegL?  Double up 2 adjacent RegI's
      // into a single RegL.
      else if( (i&1) == 0 &&
          _register_save_type[i  ] == Op_RegI &&
          _register_save_type[i+1] == Op_RegI &&
        is_save_on_entry(i+1) ) {
        // Add other bit for long
        ret_rms      [      ret_edge_cnt].Insert(OptoReg::Name(i+1));
        reth_rms     [     reth_edge_cnt].Insert(OptoReg::Name(i+1));
        tail_call_rms[tail_call_edge_cnt].Insert(OptoReg::Name(i+1));
        tail_jump_rms[tail_jump_edge_cnt].Insert(OptoReg::Name(i+1));
        halt_rms     [     halt_edge_cnt].Insert(OptoReg::Name(i+1));
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        mproj = new (C) MachProjNode( start, proj_cnt, ret_rms[ret_edge_cnt], Op_RegL );
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        proj_cnt += 2;          // Skip 2 for longs
      }
      else if( (i&1) == 1 &&    // Else check for high half of long
               _register_save_type[i-1] == Op_RegI &&
               _register_save_type[i  ] == Op_RegI &&
               is_save_on_entry(i-1) ) {
        ret_rms      [      ret_edge_cnt] = RegMask::Empty;
        reth_rms     [     reth_edge_cnt] = RegMask::Empty;
        tail_call_rms[tail_call_edge_cnt] = RegMask::Empty;
        tail_jump_rms[tail_jump_edge_cnt] = RegMask::Empty;
        halt_rms     [     halt_edge_cnt] = RegMask::Empty;
        mproj = C->top();
      } else {
        // Make a projection for it off the Start
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        mproj = new (C) MachProjNode( start, proj_cnt++, ret_rms[ret_edge_cnt], _register_save_type[i] );
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      }

      ret_edge_cnt ++;
      reth_edge_cnt ++;
      tail_call_edge_cnt ++;
      tail_jump_edge_cnt ++;
      halt_edge_cnt ++;

      // Add a use of the SOE register to all exit paths
      for( uint j=1; j < root->req(); j++ )
        root->in(j)->add_req(mproj);
    } // End of if a save-on-entry register
  } // End of for all machine registers
}

//------------------------------init_spill_mask--------------------------------
void Matcher::init_spill_mask( Node *ret ) {
  if( idealreg2regmask[Op_RegI] ) return; // One time only init

  OptoReg::c_frame_pointer = c_frame_pointer();
  c_frame_ptr_mask = c_frame_pointer();
#ifdef _LP64
  // pointers are twice as big
  c_frame_ptr_mask.Insert(OptoReg::add(c_frame_pointer(),1));
#endif

  // Start at OptoReg::stack0()
  STACK_ONLY_mask.Clear();
  OptoReg::Name init = OptoReg::stack2reg(0);
  // STACK_ONLY_mask is all stack bits
  OptoReg::Name i;
  for (i = init; RegMask::can_represent(i); i = OptoReg::add(i,1))
    STACK_ONLY_mask.Insert(i);
  // Also set the "infinite stack" bit.
  STACK_ONLY_mask.set_AllStack();

  // Copy the register names over into the shared world
  for( i=OptoReg::Name(0); i<OptoReg::Name(_last_Mach_Reg); i = OptoReg::add(i,1) ) {
    // SharedInfo::regName[i] = regName[i];
    // Handy RegMasks per machine register
    mreg2regmask[i].Insert(i);
  }

  // Grab the Frame Pointer
  Node *fp  = ret->in(TypeFunc::FramePtr);
  Node *mem = ret->in(TypeFunc::Memory);
  const TypePtr* atp = TypePtr::BOTTOM;
  // Share frame pointer while making spill ops
  set_shared(fp);

  // Compute generic short-offset Loads
824
#ifdef _LP64
825
  MachNode *spillCP = match_tree(new (C) LoadNNode(NULL,mem,fp,atp,TypeInstPtr::BOTTOM));
826
#endif
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  MachNode *spillI  = match_tree(new (C) LoadINode(NULL,mem,fp,atp));
  MachNode *spillL  = match_tree(new (C) LoadLNode(NULL,mem,fp,atp));
  MachNode *spillF  = match_tree(new (C) LoadFNode(NULL,mem,fp,atp));
  MachNode *spillD  = match_tree(new (C) LoadDNode(NULL,mem,fp,atp));
  MachNode *spillP  = match_tree(new (C) LoadPNode(NULL,mem,fp,atp,TypeInstPtr::BOTTOM));
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  assert(spillI != NULL && spillL != NULL && spillF != NULL &&
         spillD != NULL && spillP != NULL, "");

  // Get the ADLC notion of the right regmask, for each basic type.
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#ifdef _LP64
  idealreg2regmask[Op_RegN] = &spillCP->out_RegMask();
#endif
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  idealreg2regmask[Op_RegI] = &spillI->out_RegMask();
  idealreg2regmask[Op_RegL] = &spillL->out_RegMask();
  idealreg2regmask[Op_RegF] = &spillF->out_RegMask();
  idealreg2regmask[Op_RegD] = &spillD->out_RegMask();
  idealreg2regmask[Op_RegP] = &spillP->out_RegMask();
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  // Vector regmasks.
  if (Matcher::vector_size_supported(T_BYTE,4)) {
    TypeVect::VECTS = TypeVect::make(T_BYTE, 4);
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    MachNode *spillVectS = match_tree(new (C) LoadVectorNode(NULL,mem,fp,atp,TypeVect::VECTS));
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    idealreg2regmask[Op_VecS] = &spillVectS->out_RegMask();
  }
  if (Matcher::vector_size_supported(T_FLOAT,2)) {
852
    MachNode *spillVectD = match_tree(new (C) LoadVectorNode(NULL,mem,fp,atp,TypeVect::VECTD));
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    idealreg2regmask[Op_VecD] = &spillVectD->out_RegMask();
  }
  if (Matcher::vector_size_supported(T_FLOAT,4)) {
856
    MachNode *spillVectX = match_tree(new (C) LoadVectorNode(NULL,mem,fp,atp,TypeVect::VECTX));
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    idealreg2regmask[Op_VecX] = &spillVectX->out_RegMask();
  }
  if (Matcher::vector_size_supported(T_FLOAT,8)) {
860
    MachNode *spillVectY = match_tree(new (C) LoadVectorNode(NULL,mem,fp,atp,TypeVect::VECTY));
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    idealreg2regmask[Op_VecY] = &spillVectY->out_RegMask();
  }
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}

#ifdef ASSERT
static void match_alias_type(Compile* C, Node* n, Node* m) {
  if (!VerifyAliases)  return;  // do not go looking for trouble by default
  const TypePtr* nat = n->adr_type();
  const TypePtr* mat = m->adr_type();
  int nidx = C->get_alias_index(nat);
  int midx = C->get_alias_index(mat);
  // Detune the assert for cases like (AndI 0xFF (LoadB p)).
  if (nidx == Compile::AliasIdxTop && midx >= Compile::AliasIdxRaw) {
    for (uint i = 1; i < n->req(); i++) {
      Node* n1 = n->in(i);
      const TypePtr* n1at = n1->adr_type();
      if (n1at != NULL) {
        nat = n1at;
        nidx = C->get_alias_index(n1at);
      }
    }
  }
  // %%% Kludgery.  Instead, fix ideal adr_type methods for all these cases:
  if (nidx == Compile::AliasIdxTop && midx == Compile::AliasIdxRaw) {
    switch (n->Opcode()) {
    case Op_PrefetchRead:
    case Op_PrefetchWrite:
888
    case Op_PrefetchAllocation:
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      nidx = Compile::AliasIdxRaw;
      nat = TypeRawPtr::BOTTOM;
      break;
    }
  }
  if (nidx == Compile::AliasIdxRaw && midx == Compile::AliasIdxTop) {
    switch (n->Opcode()) {
    case Op_ClearArray:
      midx = Compile::AliasIdxRaw;
      mat = TypeRawPtr::BOTTOM;
      break;
    }
  }
  if (nidx == Compile::AliasIdxTop && midx == Compile::AliasIdxBot) {
    switch (n->Opcode()) {
    case Op_Return:
    case Op_Rethrow:
    case Op_Halt:
    case Op_TailCall:
    case Op_TailJump:
      nidx = Compile::AliasIdxBot;
      nat = TypePtr::BOTTOM;
      break;
    }
  }
  if (nidx == Compile::AliasIdxBot && midx == Compile::AliasIdxTop) {
    switch (n->Opcode()) {
    case Op_StrComp:
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    case Op_StrEquals:
    case Op_StrIndexOf:
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    case Op_AryEq:
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    case Op_MemBarVolatile:
    case Op_MemBarCPUOrder: // %%% these ideals should have narrower adr_type?
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    case Op_EncodeISOArray:
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      nidx = Compile::AliasIdxTop;
      nat = NULL;
      break;
    }
  }
  if (nidx != midx) {
    if (PrintOpto || (PrintMiscellaneous && (WizardMode || Verbose))) {
      tty->print_cr("==== Matcher alias shift %d => %d", nidx, midx);
      n->dump();
      m->dump();
    }
    assert(C->subsume_loads() && C->must_alias(nat, midx),
           "must not lose alias info when matching");
  }
}
#endif


//------------------------------MStack-----------------------------------------
// State and MStack class used in xform() and find_shared() iterative methods.
enum Node_State { Pre_Visit,  // node has to be pre-visited
                      Visit,  // visit node
                 Post_Visit,  // post-visit node
             Alt_Post_Visit   // alternative post-visit path
                };

class MStack: public Node_Stack {
  public:
    MStack(int size) : Node_Stack(size) { }

    void push(Node *n, Node_State ns) {
      Node_Stack::push(n, (uint)ns);
    }
    void push(Node *n, Node_State ns, Node *parent, int indx) {
      ++_inode_top;
      if ((_inode_top + 1) >= _inode_max) grow();
      _inode_top->node = parent;
      _inode_top->indx = (uint)indx;
      ++_inode_top;
      _inode_top->node = n;
      _inode_top->indx = (uint)ns;
    }
    Node *parent() {
      pop();
      return node();
    }
    Node_State state() const {
      return (Node_State)index();
    }
    void set_state(Node_State ns) {
      set_index((uint)ns);
    }
};


//------------------------------xform------------------------------------------
// Given a Node in old-space, Match him (Label/Reduce) to produce a machine
// Node in new-space.  Given a new-space Node, recursively walk his children.
Node *Matcher::transform( Node *n ) { ShouldNotCallThis(); return n; }
Node *Matcher::xform( Node *n, int max_stack ) {
  // Use one stack to keep both: child's node/state and parent's node/index
  MStack mstack(max_stack * 2 * 2); // C->unique() * 2 * 2
  mstack.push(n, Visit, NULL, -1);  // set NULL as parent to indicate root

  while (mstack.is_nonempty()) {
988 989
    C->check_node_count(NodeLimitFudgeFactor, "too many nodes matching instructions");
    if (C->failing()) return NULL;
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    n = mstack.node();          // Leave node on stack
    Node_State nstate = mstack.state();
    if (nstate == Visit) {
      mstack.set_state(Post_Visit);
      Node *oldn = n;
      // Old-space or new-space check
      if (!C->node_arena()->contains(n)) {
        // Old space!
        Node* m;
        if (has_new_node(n)) {  // Not yet Label/Reduced
          m = new_node(n);
        } else {
          if (!is_dontcare(n)) { // Matcher can match this guy
            // Calls match special.  They match alone with no children.
            // Their children, the incoming arguments, match normally.
            m = n->is_SafePoint() ? match_sfpt(n->as_SafePoint()):match_tree(n);
            if (C->failing())  return NULL;
            if (m == NULL) { Matcher::soft_match_failure(); return NULL; }
          } else {                  // Nothing the matcher cares about
            if( n->is_Proj() && n->in(0)->is_Multi()) {       // Projections?
              // Convert to machine-dependent projection
              m = n->in(0)->as_Multi()->match( n->as_Proj(), this );
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#ifdef ASSERT
              _new2old_map.map(m->_idx, n);
#endif
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              if (m->in(0) != NULL) // m might be top
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                collect_null_checks(m, n);
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            } else {                // Else just a regular 'ol guy
              m = n->clone();       // So just clone into new-space
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#ifdef ASSERT
              _new2old_map.map(m->_idx, n);
#endif
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              // Def-Use edges will be added incrementally as Uses
              // of this node are matched.
              assert(m->outcnt() == 0, "no Uses of this clone yet");
            }
          }

          set_new_node(n, m);       // Map old to new
          if (_old_node_note_array != NULL) {
            Node_Notes* nn = C->locate_node_notes(_old_node_note_array,
                                                  n->_idx);
            C->set_node_notes_at(m->_idx, nn);
          }
          debug_only(match_alias_type(C, n, m));
        }
        n = m;    // n is now a new-space node
        mstack.set_node(n);
      }

      // New space!
      if (_visited.test_set(n->_idx)) continue; // while(mstack.is_nonempty())

      int i;
      // Put precedence edges on stack first (match them last).
      for (i = oldn->req(); (uint)i < oldn->len(); i++) {
        Node *m = oldn->in(i);
        if (m == NULL) break;
        // set -1 to call add_prec() instead of set_req() during Step1
        mstack.push(m, Visit, n, -1);
      }

      // For constant debug info, I'd rather have unmatched constants.
      int cnt = n->req();
      JVMState* jvms = n->jvms();
      int debug_cnt = jvms ? jvms->debug_start() : cnt;

      // Now do only debug info.  Clone constants rather than matching.
      // Constants are represented directly in the debug info without
      // the need for executable machine instructions.
      // Monitor boxes are also represented directly.
      for (i = cnt - 1; i >= debug_cnt; --i) { // For all debug inputs do
        Node *m = n->in(i);          // Get input
        int op = m->Opcode();
        assert((op == Op_BoxLock) == jvms->is_monitor_use(i), "boxes only at monitor sites");
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        if( op == Op_ConI || op == Op_ConP || op == Op_ConN || op == Op_ConNKlass ||
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            op == Op_ConF || op == Op_ConD || op == Op_ConL
            // || op == Op_BoxLock  // %%%% enable this and remove (+++) in chaitin.cpp
            ) {
          m = m->clone();
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#ifdef ASSERT
          _new2old_map.map(m->_idx, n);
#endif
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          mstack.push(m, Post_Visit, n, i); // Don't need to visit
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          mstack.push(m->in(0), Visit, m, 0);
        } else {
          mstack.push(m, Visit, n, i);
        }
      }

      // And now walk his children, and convert his inputs to new-space.
      for( ; i >= 0; --i ) { // For all normal inputs do
        Node *m = n->in(i);  // Get input
        if(m != NULL)
          mstack.push(m, Visit, n, i);
      }

    }
    else if (nstate == Post_Visit) {
      // Set xformed input
      Node *p = mstack.parent();
      if (p != NULL) { // root doesn't have parent
        int i = (int)mstack.index();
        if (i >= 0)
          p->set_req(i, n); // required input
        else if (i == -1)
          p->add_prec(n);   // precedence input
        else
          ShouldNotReachHere();
      }
      mstack.pop(); // remove processed node from stack
    }
    else {
      ShouldNotReachHere();
    }
  } // while (mstack.is_nonempty())
  return n; // Return new-space Node
}

//------------------------------warp_outgoing_stk_arg------------------------
OptoReg::Name Matcher::warp_outgoing_stk_arg( VMReg reg, OptoReg::Name begin_out_arg_area, OptoReg::Name &out_arg_limit_per_call ) {
  // Convert outgoing argument location to a pre-biased stack offset
  if (reg->is_stack()) {
    OptoReg::Name warped = reg->reg2stack();
    // Adjust the stack slot offset to be the register number used
    // by the allocator.
    warped = OptoReg::add(begin_out_arg_area, warped);
    // Keep track of the largest numbered stack slot used for an arg.
    // Largest used slot per call-site indicates the amount of stack
    // that is killed by the call.
    if( warped >= out_arg_limit_per_call )
      out_arg_limit_per_call = OptoReg::add(warped,1);
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    if (!RegMask::can_represent_arg(warped)) {
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      C->record_method_not_compilable_all_tiers("unsupported calling sequence");
      return OptoReg::Bad;
    }
    return warped;
  }
  return OptoReg::as_OptoReg(reg);
}


//------------------------------match_sfpt-------------------------------------
// Helper function to match call instructions.  Calls match special.
// They match alone with no children.  Their children, the incoming
// arguments, match normally.
MachNode *Matcher::match_sfpt( SafePointNode *sfpt ) {
  MachSafePointNode *msfpt = NULL;
  MachCallNode      *mcall = NULL;
  uint               cnt;
  // Split out case for SafePoint vs Call
  CallNode *call;
  const TypeTuple *domain;
  ciMethod*        method = NULL;
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  bool             is_method_handle_invoke = false;  // for special kill effects
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  if( sfpt->is_Call() ) {
    call = sfpt->as_Call();
    domain = call->tf()->domain();
    cnt = domain->cnt();

    // Match just the call, nothing else
    MachNode *m = match_tree(call);
    if (C->failing())  return NULL;
    if( m == NULL ) { Matcher::soft_match_failure(); return NULL; }

    // Copy data from the Ideal SafePoint to the machine version
    mcall = m->as_MachCall();

    mcall->set_tf(         call->tf());
    mcall->set_entry_point(call->entry_point());
    mcall->set_cnt(        call->cnt());

    if( mcall->is_MachCallJava() ) {
      MachCallJavaNode *mcall_java  = mcall->as_MachCallJava();
      const CallJavaNode *call_java =  call->as_CallJava();
      method = call_java->method();
      mcall_java->_method = method;
      mcall_java->_bci = call_java->_bci;
      mcall_java->_optimized_virtual = call_java->is_optimized_virtual();
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      is_method_handle_invoke = call_java->is_method_handle_invoke();
      mcall_java->_method_handle_invoke = is_method_handle_invoke;
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      if (is_method_handle_invoke) {
        C->set_has_method_handle_invokes(true);
      }
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      if( mcall_java->is_MachCallStaticJava() )
        mcall_java->as_MachCallStaticJava()->_name =
         call_java->as_CallStaticJava()->_name;
      if( mcall_java->is_MachCallDynamicJava() )
        mcall_java->as_MachCallDynamicJava()->_vtable_index =
         call_java->as_CallDynamicJava()->_vtable_index;
    }
    else if( mcall->is_MachCallRuntime() ) {
      mcall->as_MachCallRuntime()->_name = call->as_CallRuntime()->_name;
    }
    msfpt = mcall;
  }
  // This is a non-call safepoint
  else {
    call = NULL;
    domain = NULL;
    MachNode *mn = match_tree(sfpt);
    if (C->failing())  return NULL;
    msfpt = mn->as_MachSafePoint();
    cnt = TypeFunc::Parms;
  }

  // Advertise the correct memory effects (for anti-dependence computation).
  msfpt->set_adr_type(sfpt->adr_type());

  // Allocate a private array of RegMasks.  These RegMasks are not shared.
  msfpt->_in_rms = NEW_RESOURCE_ARRAY( RegMask, cnt );
  // Empty them all.
  memset( msfpt->_in_rms, 0, sizeof(RegMask)*cnt );

  // Do all the pre-defined non-Empty register masks
  msfpt->_in_rms[TypeFunc::ReturnAdr] = _return_addr_mask;
  msfpt->_in_rms[TypeFunc::FramePtr ] = c_frame_ptr_mask;

  // Place first outgoing argument can possibly be put.
  OptoReg::Name begin_out_arg_area = OptoReg::add(_new_SP, C->out_preserve_stack_slots());
  assert( is_even(begin_out_arg_area), "" );
  // Compute max outgoing register number per call site.
  OptoReg::Name out_arg_limit_per_call = begin_out_arg_area;
  // Calls to C may hammer extra stack slots above and beyond any arguments.
  // These are usually backing store for register arguments for varargs.
  if( call != NULL && call->is_CallRuntime() )
    out_arg_limit_per_call = OptoReg::add(out_arg_limit_per_call,C->varargs_C_out_slots_killed());


  // Do the normal argument list (parameters) register masks
  int argcnt = cnt - TypeFunc::Parms;
  if( argcnt > 0 ) {          // Skip it all if we have no args
    BasicType *sig_bt  = NEW_RESOURCE_ARRAY( BasicType, argcnt );
    VMRegPair *parm_regs = NEW_RESOURCE_ARRAY( VMRegPair, argcnt );
    int i;
    for( i = 0; i < argcnt; i++ ) {
      sig_bt[i] = domain->field_at(i+TypeFunc::Parms)->basic_type();
    }
    // V-call to pick proper calling convention
    call->calling_convention( sig_bt, parm_regs, argcnt );

#ifdef ASSERT
    // Sanity check users' calling convention.  Really handy during
    // the initial porting effort.  Fairly expensive otherwise.
    { for (int i = 0; i<argcnt; i++) {
      if( !parm_regs[i].first()->is_valid() &&
          !parm_regs[i].second()->is_valid() ) continue;
      VMReg reg1 = parm_regs[i].first();
      VMReg reg2 = parm_regs[i].second();
      for (int j = 0; j < i; j++) {
        if( !parm_regs[j].first()->is_valid() &&
            !parm_regs[j].second()->is_valid() ) continue;
        VMReg reg3 = parm_regs[j].first();
        VMReg reg4 = parm_regs[j].second();
        if( !reg1->is_valid() ) {
          assert( !reg2->is_valid(), "valid halvsies" );
        } else if( !reg3->is_valid() ) {
          assert( !reg4->is_valid(), "valid halvsies" );
        } else {
          assert( reg1 != reg2, "calling conv. must produce distinct regs");
          assert( reg1 != reg3, "calling conv. must produce distinct regs");
          assert( reg1 != reg4, "calling conv. must produce distinct regs");
          assert( reg2 != reg3, "calling conv. must produce distinct regs");
          assert( reg2 != reg4 || !reg2->is_valid(), "calling conv. must produce distinct regs");
          assert( reg3 != reg4, "calling conv. must produce distinct regs");
        }
      }
    }
    }
#endif

    // Visit each argument.  Compute its outgoing register mask.
    // Return results now can have 2 bits returned.
    // Compute max over all outgoing arguments both per call-site
    // and over the entire method.
    for( i = 0; i < argcnt; i++ ) {
      // Address of incoming argument mask to fill in
      RegMask *rm = &mcall->_in_rms[i+TypeFunc::Parms];
      if( !parm_regs[i].first()->is_valid() &&
          !parm_regs[i].second()->is_valid() ) {
        continue;               // Avoid Halves
      }
      // Grab first register, adjust stack slots and insert in mask.
      OptoReg::Name reg1 = warp_outgoing_stk_arg(parm_regs[i].first(), begin_out_arg_area, out_arg_limit_per_call );
      if (OptoReg::is_valid(reg1))
        rm->Insert( reg1 );
      // Grab second register (if any), adjust stack slots and insert in mask.
      OptoReg::Name reg2 = warp_outgoing_stk_arg(parm_regs[i].second(), begin_out_arg_area, out_arg_limit_per_call );
      if (OptoReg::is_valid(reg2))
        rm->Insert( reg2 );
    } // End of for all arguments

    // Compute number of stack slots needed to restore stack in case of
    // Pascal-style argument popping.
    mcall->_argsize = out_arg_limit_per_call - begin_out_arg_area;
  }

  // Compute the max stack slot killed by any call.  These will not be
  // available for debug info, and will be used to adjust FIRST_STACK_mask
  // after all call sites have been visited.
  if( _out_arg_limit < out_arg_limit_per_call)
    _out_arg_limit = out_arg_limit_per_call;

  if (mcall) {
    // Kill the outgoing argument area, including any non-argument holes and
    // any legacy C-killed slots.  Use Fat-Projections to do the killing.
    // Since the max-per-method covers the max-per-call-site and debug info
    // is excluded on the max-per-method basis, debug info cannot land in
    // this killed area.
    uint r_cnt = mcall->tf()->range()->cnt();
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    MachProjNode *proj = new (C) MachProjNode( mcall, r_cnt+10000, RegMask::Empty, MachProjNode::fat_proj );
1301
    if (!RegMask::can_represent_arg(OptoReg::Name(out_arg_limit_per_call-1))) {
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      C->record_method_not_compilable_all_tiers("unsupported outgoing calling sequence");
    } else {
      for (int i = begin_out_arg_area; i < out_arg_limit_per_call; i++)
        proj->_rout.Insert(OptoReg::Name(i));
    }
    if( proj->_rout.is_NotEmpty() )
      _proj_list.push(proj);
  }
  // Transfer the safepoint information from the call to the mcall
  // Move the JVMState list
  msfpt->set_jvms(sfpt->jvms());
  for (JVMState* jvms = msfpt->jvms(); jvms; jvms = jvms->caller()) {
    jvms->set_map(sfpt);
  }

  // Debug inputs begin just after the last incoming parameter
  assert( (mcall == NULL) || (mcall->jvms() == NULL) ||
          (mcall->jvms()->debug_start() + mcall->_jvmadj == mcall->tf()->domain()->cnt()), "" );

  // Move the OopMap
  msfpt->_oop_map = sfpt->_oop_map;

  // Registers killed by the call are set in the local scheduling pass
  // of Global Code Motion.
  return msfpt;
}

//---------------------------match_tree----------------------------------------
// Match a Ideal Node DAG - turn it into a tree; Label & Reduce.  Used as part
// of the whole-sale conversion from Ideal to Mach Nodes.  Also used for
// making GotoNodes while building the CFG and in init_spill_mask() to identify
// a Load's result RegMask for memoization in idealreg2regmask[]
MachNode *Matcher::match_tree( const Node *n ) {
  assert( n->Opcode() != Op_Phi, "cannot match" );
  assert( !n->is_block_start(), "cannot match" );
  // Set the mark for all locally allocated State objects.
  // When this call returns, the _states_arena arena will be reset
  // freeing all State objects.
  ResourceMark rm( &_states_arena );

  LabelRootDepth = 0;

  // StoreNodes require their Memory input to match any LoadNodes
  Node *mem = n->is_Store() ? n->in(MemNode::Memory) : (Node*)1 ;
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#ifdef ASSERT
  Node* save_mem_node = _mem_node;
  _mem_node = n->is_Store() ? (Node*)n : NULL;
#endif
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  // State object for root node of match tree
  // Allocate it on _states_arena - stack allocation can cause stack overflow.
  State *s = new (&_states_arena) State;
  s->_kids[0] = NULL;
  s->_kids[1] = NULL;
  s->_leaf = (Node*)n;
  // Label the input tree, allocating labels from top-level arena
  Label_Root( n, s, n->in(0), mem );
  if (C->failing())  return NULL;

  // The minimum cost match for the whole tree is found at the root State
  uint mincost = max_juint;
  uint cost = max_juint;
  uint i;
  for( i = 0; i < NUM_OPERANDS; i++ ) {
    if( s->valid(i) &&                // valid entry and
        s->_cost[i] < cost &&         // low cost and
        s->_rule[i] >= NUM_OPERANDS ) // not an operand
      cost = s->_cost[mincost=i];
  }
  if (mincost == max_juint) {
#ifndef PRODUCT
    tty->print("No matching rule for:");
    s->dump();
#endif
    Matcher::soft_match_failure();
    return NULL;
  }
  // Reduce input tree based upon the state labels to machine Nodes
  MachNode *m = ReduceInst( s, s->_rule[mincost], mem );
#ifdef ASSERT
  _old2new_map.map(n->_idx, m);
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  _new2old_map.map(m->_idx, (Node*)n);
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#endif

  // Add any Matcher-ignored edges
  uint cnt = n->req();
  uint start = 1;
  if( mem != (Node*)1 ) start = MemNode::Memory+1;
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  if( n->is_AddP() ) {
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    assert( mem == (Node*)1, "" );
    start = AddPNode::Base+1;
  }
  for( i = start; i < cnt; i++ ) {
    if( !n->match_edge(i) ) {
      if( i < m->req() )
        m->ins_req( i, n->in(i) );
      else
        m->add_req( n->in(i) );
    }
  }

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  debug_only( _mem_node = save_mem_node; )
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  return m;
}


//------------------------------match_into_reg---------------------------------
// Choose to either match this Node in a register or part of the current
// match tree.  Return true for requiring a register and false for matching
// as part of the current match tree.
static bool match_into_reg( const Node *n, Node *m, Node *control, int i, bool shared ) {

  const Type *t = m->bottom_type();

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  if (t->singleton()) {
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    // Never force constants into registers.  Allow them to match as
    // constants or registers.  Copies of the same value will share
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    // the same register.  See find_shared_node.
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    return false;
  } else {                      // Not a constant
    // Stop recursion if they have different Controls.
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    Node* m_control = m->in(0);
    // Control of load's memory can post-dominates load's control.
    // So use it since load can't float above its memory.
    Node* mem_control = (m->is_Load()) ? m->in(MemNode::Memory)->in(0) : NULL;
    if (control && m_control && control != m_control && control != mem_control) {
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      // Actually, we can live with the most conservative control we
      // find, if it post-dominates the others.  This allows us to
      // pick up load/op/store trees where the load can float a little
      // above the store.
      Node *x = control;
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      const uint max_scan = 6;  // Arbitrary scan cutoff
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      uint j;
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      for (j=0; j<max_scan; j++) {
        if (x->is_Region())     // Bail out at merge points
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          return true;
        x = x->in(0);
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        if (x == m_control)     // Does 'control' post-dominate
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          break;                // m->in(0)?  If so, we can use it
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        if (x == mem_control)   // Does 'control' post-dominate
          break;                // mem_control?  If so, we can use it
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      }
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      if (j == max_scan)        // No post-domination before scan end?
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        return true;            // Then break the match tree up
    }
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    if ((m->is_DecodeN() && Matcher::narrow_oop_use_complex_address()) ||
        (m->is_DecodeNKlass() && Matcher::narrow_klass_use_complex_address())) {
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      // These are commonly used in address expressions and can
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      // efficiently fold into them on X64 in some cases.
      return false;
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    }
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  }

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  // Not forceable cloning.  If shared, put it into a register.
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  return shared;
}


//------------------------------Instruction Selection--------------------------
// Label method walks a "tree" of nodes, using the ADLC generated DFA to match
// ideal nodes to machine instructions.  Trees are delimited by shared Nodes,
// things the Matcher does not match (e.g., Memory), and things with different
// Controls (hence forced into different blocks).  We pass in the Control
// selected for this entire State tree.

// The Matcher works on Trees, but an Intel add-to-memory requires a DAG: the
// Store and the Load must have identical Memories (as well as identical
// pointers).  Since the Matcher does not have anything for Memory (and
// does not handle DAGs), I have to match the Memory input myself.  If the
// Tree root is a Store, I require all Loads to have the identical memory.
Node *Matcher::Label_Root( const Node *n, State *svec, Node *control, const Node *mem){
  // Since Label_Root is a recursive function, its possible that we might run
  // out of stack space.  See bugs 6272980 & 6227033 for more info.
  LabelRootDepth++;
  if (LabelRootDepth > MaxLabelRootDepth) {
    C->record_method_not_compilable_all_tiers("Out of stack space, increase MaxLabelRootDepth");
    return NULL;
  }
  uint care = 0;                // Edges matcher cares about
  uint cnt = n->req();
  uint i = 0;

  // Examine children for memory state
  // Can only subsume a child into your match-tree if that child's memory state
  // is not modified along the path to another input.
  // It is unsafe even if the other inputs are separate roots.
  Node *input_mem = NULL;
  for( i = 1; i < cnt; i++ ) {
    if( !n->match_edge(i) ) continue;
    Node *m = n->in(i);         // Get ith input
    assert( m, "expect non-null children" );
    if( m->is_Load() ) {
      if( input_mem == NULL ) {
        input_mem = m->in(MemNode::Memory);
      } else if( input_mem != m->in(MemNode::Memory) ) {
        input_mem = NodeSentinel;
      }
    }
  }

  for( i = 1; i < cnt; i++ ){// For my children
    if( !n->match_edge(i) ) continue;
    Node *m = n->in(i);         // Get ith input
    // Allocate states out of a private arena
    State *s = new (&_states_arena) State;
    svec->_kids[care++] = s;
    assert( care <= 2, "binary only for now" );

    // Recursively label the State tree.
    s->_kids[0] = NULL;
    s->_kids[1] = NULL;
    s->_leaf = m;

    // Check for leaves of the State Tree; things that cannot be a part of
    // the current tree.  If it finds any, that value is matched as a
    // register operand.  If not, then the normal matching is used.
    if( match_into_reg(n, m, control, i, is_shared(m)) ||
        //
        // Stop recursion if this is LoadNode and the root of this tree is a
        // StoreNode and the load & store have different memories.
        ((mem!=(Node*)1) && m->is_Load() && m->in(MemNode::Memory) != mem) ||
        // Can NOT include the match of a subtree when its memory state
        // is used by any of the other subtrees
        (input_mem == NodeSentinel) ) {
#ifndef PRODUCT
      // Print when we exclude matching due to different memory states at input-loads
      if( PrintOpto && (Verbose && WizardMode) && (input_mem == NodeSentinel)
        && !((mem!=(Node*)1) && m->is_Load() && m->in(MemNode::Memory) != mem) ) {
        tty->print_cr("invalid input_mem");
      }
#endif
      // Switch to a register-only opcode; this value must be in a register
      // and cannot be subsumed as part of a larger instruction.
      s->DFA( m->ideal_reg(), m );

    } else {
      // If match tree has no control and we do, adopt it for entire tree
      if( control == NULL && m->in(0) != NULL && m->req() > 1 )
        control = m->in(0);         // Pick up control
      // Else match as a normal part of the match tree.
      control = Label_Root(m,s,control,mem);
      if (C->failing()) return NULL;
    }
  }


  // Call DFA to match this node, and return
  svec->DFA( n->Opcode(), n );

#ifdef ASSERT
  uint x;
  for( x = 0; x < _LAST_MACH_OPER; x++ )
    if( svec->valid(x) )
      break;

  if (x >= _LAST_MACH_OPER) {
    n->dump();
    svec->dump();
    assert( false, "bad AD file" );
  }
#endif
  return control;
}


// Con nodes reduced using the same rule can share their MachNode
// which reduces the number of copies of a constant in the final
// program.  The register allocator is free to split uses later to
// split live ranges.
1571
MachNode* Matcher::find_shared_node(Node* leaf, uint rule) {
1572
  if (!leaf->is_Con() && !leaf->is_DecodeNarrowPtr()) return NULL;
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  // See if this Con has already been reduced using this rule.
1575 1576
  if (_shared_nodes.Size() <= leaf->_idx) return NULL;
  MachNode* last = (MachNode*)_shared_nodes.at(leaf->_idx);
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  if (last != NULL && rule == last->rule()) {
1578
    // Don't expect control change for DecodeN
1579
    if (leaf->is_DecodeNarrowPtr())
1580
      return last;
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    // Get the new space root.
    Node* xroot = new_node(C->root());
    if (xroot == NULL) {
      // This shouldn't happen give the order of matching.
      return NULL;
    }

    // Shared constants need to have their control be root so they
    // can be scheduled properly.
    Node* control = last->in(0);
    if (control != xroot) {
      if (control == NULL || control == C->root()) {
        last->set_req(0, xroot);
      } else {
        assert(false, "unexpected control");
        return NULL;
      }
    }
    return last;
  }
  return NULL;
}


//------------------------------ReduceInst-------------------------------------
// Reduce a State tree (with given Control) into a tree of MachNodes.
// This routine (and it's cohort ReduceOper) convert Ideal Nodes into
// complicated machine Nodes.  Each MachNode covers some tree of Ideal Nodes.
// Each MachNode has a number of complicated MachOper operands; each
// MachOper also covers a further tree of Ideal Nodes.

// The root of the Ideal match tree is always an instruction, so we enter
// the recursion here.  After building the MachNode, we need to recurse
// the tree checking for these cases:
// (1) Child is an instruction -
//     Build the instruction (recursively), add it as an edge.
//     Build a simple operand (register) to hold the result of the instruction.
// (2) Child is an interior part of an instruction -
//     Skip over it (do nothing)
// (3) Child is the start of a operand -
//     Build the operand, place it inside the instruction
//     Call ReduceOper.
MachNode *Matcher::ReduceInst( State *s, int rule, Node *&mem ) {
  assert( rule >= NUM_OPERANDS, "called with operand rule" );

1626 1627 1628
  MachNode* shared_node = find_shared_node(s->_leaf, rule);
  if (shared_node != NULL) {
    return shared_node;
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  }

  // Build the object to represent this state & prepare for recursive calls
  MachNode *mach = s->MachNodeGenerator( rule, C );
  mach->_opnds[0] = s->MachOperGenerator( _reduceOp[rule], C );
  assert( mach->_opnds[0] != NULL, "Missing result operand" );
  Node *leaf = s->_leaf;
  // Check for instruction or instruction chain rule
  if( rule >= _END_INST_CHAIN_RULE || rule < _BEGIN_INST_CHAIN_RULE ) {
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    assert(C->node_arena()->contains(s->_leaf) || !has_new_node(s->_leaf),
           "duplicating node that's already been matched");
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    // Instruction
    mach->add_req( leaf->in(0) ); // Set initial control
    // Reduce interior of complex instruction
    ReduceInst_Interior( s, rule, mem, mach, 1 );
  } else {
    // Instruction chain rules are data-dependent on their inputs
    mach->add_req(0);             // Set initial control to none
    ReduceInst_Chain_Rule( s, rule, mem, mach );
  }

  // If a Memory was used, insert a Memory edge
1651
  if( mem != (Node*)1 ) {
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    mach->ins_req(MemNode::Memory,mem);
1653 1654 1655
#ifdef ASSERT
    // Verify adr type after matching memory operation
    const MachOper* oper = mach->memory_operand();
1656
    if (oper != NULL && oper != (MachOper*)-1) {
1657 1658 1659 1660 1661 1662 1663 1664
      // It has a unique memory operand.  Find corresponding ideal mem node.
      Node* m = NULL;
      if (leaf->is_Mem()) {
        m = leaf;
      } else {
        m = _mem_node;
        assert(m != NULL && m->is_Mem(), "expecting memory node");
      }
1665 1666 1667
      const Type* mach_at = mach->adr_type();
      // DecodeN node consumed by an address may have different type
      // then its input. Don't compare types for such case.
1668
      if (m->adr_type() != mach_at &&
1669
          (m->in(MemNode::Address)->is_DecodeNarrowPtr() ||
1670
           m->in(MemNode::Address)->is_AddP() &&
1671
           m->in(MemNode::Address)->in(AddPNode::Address)->is_DecodeNarrowPtr() ||
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           m->in(MemNode::Address)->is_AddP() &&
           m->in(MemNode::Address)->in(AddPNode::Address)->is_AddP() &&
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           m->in(MemNode::Address)->in(AddPNode::Address)->in(AddPNode::Address)->is_DecodeNarrowPtr())) {
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        mach_at = m->adr_type();
      }
      if (m->adr_type() != mach_at) {
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        m->dump();
        tty->print_cr("mach:");
        mach->dump(1);
      }
1682
      assert(m->adr_type() == mach_at, "matcher should not change adr type");
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    }
#endif
  }
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  // If the _leaf is an AddP, insert the base edge
1688
  if( leaf->is_AddP() )
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    mach->ins_req(AddPNode::Base,leaf->in(AddPNode::Base));

  uint num_proj = _proj_list.size();

  // Perform any 1-to-many expansions required
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  MachNode *ex = mach->Expand(s,_proj_list, mem);
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  if( ex != mach ) {
    assert(ex->ideal_reg() == mach->ideal_reg(), "ideal types should match");
    if( ex->in(1)->is_Con() )
      ex->in(1)->set_req(0, C->root());
    // Remove old node from the graph
    for( uint i=0; i<mach->req(); i++ ) {
      mach->set_req(i,NULL);
    }
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#ifdef ASSERT
    _new2old_map.map(ex->_idx, s->_leaf);
#endif
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  }

  // PhaseChaitin::fixup_spills will sometimes generate spill code
  // via the matcher.  By the time, nodes have been wired into the CFG,
  // and any further nodes generated by expand rules will be left hanging
  // in space, and will not get emitted as output code.  Catch this.
  // Also, catch any new register allocation constraints ("projections")
  // generated belatedly during spill code generation.
  if (_allocation_started) {
    guarantee(ex == mach, "no expand rules during spill generation");
    guarantee(_proj_list.size() == num_proj, "no allocation during spill generation");
  }

1719
  if (leaf->is_Con() || leaf->is_DecodeNarrowPtr()) {
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    // Record the con for sharing
1721
    _shared_nodes.map(leaf->_idx, ex);
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  }

  return ex;
}

void Matcher::ReduceInst_Chain_Rule( State *s, int rule, Node *&mem, MachNode *mach ) {
  // 'op' is what I am expecting to receive
  int op = _leftOp[rule];
  // Operand type to catch childs result
  // This is what my child will give me.
  int opnd_class_instance = s->_rule[op];
  // Choose between operand class or not.
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  // This is what I will receive.
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  int catch_op = (FIRST_OPERAND_CLASS <= op && op < NUM_OPERANDS) ? opnd_class_instance : op;
  // New rule for child.  Chase operand classes to get the actual rule.
  int newrule = s->_rule[catch_op];

  if( newrule < NUM_OPERANDS ) {
    // Chain from operand or operand class, may be output of shared node
    assert( 0 <= opnd_class_instance && opnd_class_instance < NUM_OPERANDS,
            "Bad AD file: Instruction chain rule must chain from operand");
    // Insert operand into array of operands for this instruction
    mach->_opnds[1] = s->MachOperGenerator( opnd_class_instance, C );

    ReduceOper( s, newrule, mem, mach );
  } else {
    // Chain from the result of an instruction
    assert( newrule >= _LAST_MACH_OPER, "Do NOT chain from internal operand");
    mach->_opnds[1] = s->MachOperGenerator( _reduceOp[catch_op], C );
    Node *mem1 = (Node*)1;
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    debug_only(Node *save_mem_node = _mem_node;)
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    mach->add_req( ReduceInst(s, newrule, mem1) );
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    debug_only(_mem_node = save_mem_node;)
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  }
  return;
}


uint Matcher::ReduceInst_Interior( State *s, int rule, Node *&mem, MachNode *mach, uint num_opnds ) {
  if( s->_leaf->is_Load() ) {
    Node *mem2 = s->_leaf->in(MemNode::Memory);
    assert( mem == (Node*)1 || mem == mem2, "multiple Memories being matched at once?" );
1764
    debug_only( if( mem == (Node*)1 ) _mem_node = s->_leaf;)
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    mem = mem2;
  }
  if( s->_leaf->in(0) != NULL && s->_leaf->req() > 1) {
    if( mach->in(0) == NULL )
      mach->set_req(0, s->_leaf->in(0));
  }

  // Now recursively walk the state tree & add operand list.
  for( uint i=0; i<2; i++ ) {   // binary tree
    State *newstate = s->_kids[i];
    if( newstate == NULL ) break;      // Might only have 1 child
    // 'op' is what I am expecting to receive
    int op;
    if( i == 0 ) {
      op = _leftOp[rule];
    } else {
      op = _rightOp[rule];
    }
    // Operand type to catch childs result
    // This is what my child will give me.
    int opnd_class_instance = newstate->_rule[op];
    // Choose between operand class or not.
    // This is what I will receive.
    int catch_op = (op >= FIRST_OPERAND_CLASS && op < NUM_OPERANDS) ? opnd_class_instance : op;
    // New rule for child.  Chase operand classes to get the actual rule.
    int newrule = newstate->_rule[catch_op];

    if( newrule < NUM_OPERANDS ) { // Operand/operandClass or internalOp/instruction?
      // Operand/operandClass
      // Insert operand into array of operands for this instruction
      mach->_opnds[num_opnds++] = newstate->MachOperGenerator( opnd_class_instance, C );
      ReduceOper( newstate, newrule, mem, mach );

    } else {                    // Child is internal operand or new instruction
      if( newrule < _LAST_MACH_OPER ) { // internal operand or instruction?
        // internal operand --> call ReduceInst_Interior
        // Interior of complex instruction.  Do nothing but recurse.
        num_opnds = ReduceInst_Interior( newstate, newrule, mem, mach, num_opnds );
      } else {
        // instruction --> call build operand(  ) to catch result
        //             --> ReduceInst( newrule )
        mach->_opnds[num_opnds++] = s->MachOperGenerator( _reduceOp[catch_op], C );
        Node *mem1 = (Node*)1;
1808
        debug_only(Node *save_mem_node = _mem_node;)
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        mach->add_req( ReduceInst( newstate, newrule, mem1 ) );
1810
        debug_only(_mem_node = save_mem_node;)
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      }
    }
    assert( mach->_opnds[num_opnds-1], "" );
  }
  return num_opnds;
}

// This routine walks the interior of possible complex operands.
// At each point we check our children in the match tree:
// (1) No children -
//     We are a leaf; add _leaf field as an input to the MachNode
// (2) Child is an internal operand -
//     Skip over it ( do nothing )
// (3) Child is an instruction -
//     Call ReduceInst recursively and
//     and instruction as an input to the MachNode
void Matcher::ReduceOper( State *s, int rule, Node *&mem, MachNode *mach ) {
  assert( rule < _LAST_MACH_OPER, "called with operand rule" );
  State *kid = s->_kids[0];
  assert( kid == NULL || s->_leaf->in(0) == NULL, "internal operands have no control" );

  // Leaf?  And not subsumed?
  if( kid == NULL && !_swallowed[rule] ) {
    mach->add_req( s->_leaf );  // Add leaf pointer
    return;                     // Bail out
  }

  if( s->_leaf->is_Load() ) {
    assert( mem == (Node*)1, "multiple Memories being matched at once?" );
    mem = s->_leaf->in(MemNode::Memory);
1841
    debug_only(_mem_node = s->_leaf;)
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  }
  if( s->_leaf->in(0) && s->_leaf->req() > 1) {
    if( !mach->in(0) )
      mach->set_req(0,s->_leaf->in(0));
    else {
      assert( s->_leaf->in(0) == mach->in(0), "same instruction, differing controls?" );
    }
  }

  for( uint i=0; kid != NULL && i<2; kid = s->_kids[1], i++ ) {   // binary tree
    int newrule;
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    if( i == 0)
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      newrule = kid->_rule[_leftOp[rule]];
    else
      newrule = kid->_rule[_rightOp[rule]];

    if( newrule < _LAST_MACH_OPER ) { // Operand or instruction?
      // Internal operand; recurse but do nothing else
      ReduceOper( kid, newrule, mem, mach );

    } else {                    // Child is a new instruction
      // Reduce the instruction, and add a direct pointer from this
      // machine instruction to the newly reduced one.
      Node *mem1 = (Node*)1;
1866
      debug_only(Node *save_mem_node = _mem_node;)
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      mach->add_req( ReduceInst( kid, newrule, mem1 ) );
1868
      debug_only(_mem_node = save_mem_node;)
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    }
  }
}


// -------------------------------------------------------------------------
// Java-Java calling convention
// (what you use when Java calls Java)

//------------------------------find_receiver----------------------------------
// For a given signature, return the OptoReg for parameter 0.
OptoReg::Name Matcher::find_receiver( bool is_outgoing ) {
  VMRegPair regs;
  BasicType sig_bt = T_OBJECT;
  calling_convention(&sig_bt, &regs, 1, is_outgoing);
  // Return argument 0 register.  In the LP64 build pointers
  // take 2 registers, but the VM wants only the 'main' name.
  return OptoReg::as_OptoReg(regs.first());
}

// A method-klass-holder may be passed in the inline_cache_reg
// and then expanded into the inline_cache_reg and a method_oop register
//   defined in ad_<arch>.cpp


//------------------------------find_shared------------------------------------
// Set bits if Node is shared or otherwise a root
void Matcher::find_shared( Node *n ) {
  // Allocate stack of size C->unique() * 2 to avoid frequent realloc
  MStack mstack(C->unique() * 2);
1899 1900
  // Mark nodes as address_visited if they are inputs to an address expression
  VectorSet address_visited(Thread::current()->resource_area());
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  mstack.push(n, Visit);     // Don't need to pre-visit root node
  while (mstack.is_nonempty()) {
    n = mstack.node();       // Leave node on stack
    Node_State nstate = mstack.state();
1905
    uint nop = n->Opcode();
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    if (nstate == Pre_Visit) {
1907 1908 1909 1910
      if (address_visited.test(n->_idx)) { // Visited in address already?
        // Flag as visited and shared now.
        set_visited(n);
      }
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      if (is_visited(n)) {   // Visited already?
        // Node is shared and has no reason to clone.  Flag it as shared.
        // This causes it to match into a register for the sharing.
        set_shared(n);       // Flag as shared and
        mstack.pop();        // remove node from stack
        continue;
      }
      nstate = Visit; // Not already visited; so visit now
    }
    if (nstate == Visit) {
      mstack.set_state(Post_Visit);
      set_visited(n);   // Flag as visited now
      bool mem_op = false;

1925
      switch( nop ) {  // Handle some opcodes special
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      case Op_Phi:             // Treat Phis as shared roots
      case Op_Parm:
      case Op_Proj:            // All handled specially during matching
1929
      case Op_SafePointScalarObject:
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        set_shared(n);
        set_dontcare(n);
        break;
      case Op_If:
      case Op_CountedLoopEnd:
        mstack.set_state(Alt_Post_Visit); // Alternative way
        // Convert (If (Bool (CmpX A B))) into (If (Bool) (CmpX A B)).  Helps
        // with matching cmp/branch in 1 instruction.  The Matcher needs the
        // Bool and CmpX side-by-side, because it can only get at constants
        // that are at the leaves of Match trees, and the Bool's condition acts
        // as a constant here.
        mstack.push(n->in(1), Visit);         // Clone the Bool
        mstack.push(n->in(0), Pre_Visit);     // Visit control input
        continue; // while (mstack.is_nonempty())
      case Op_ConvI2D:         // These forms efficiently match with a prior
      case Op_ConvI2F:         //   Load but not a following Store
        if( n->in(1)->is_Load() &&        // Prior load
            n->outcnt() == 1 &&           // Not already shared
            n->unique_out()->is_Store() ) // Following store
          set_shared(n);       // Force it to be a root
        break;
      case Op_ReverseBytesI:
      case Op_ReverseBytesL:
        if( n->in(1)->is_Load() &&        // Prior load
            n->outcnt() == 1 )            // Not already shared
          set_shared(n);                  // Force it to be a root
        break;
      case Op_BoxLock:         // Cant match until we get stack-regs in ADLC
      case Op_IfFalse:
      case Op_IfTrue:
      case Op_MachProj:
      case Op_MergeMem:
      case Op_Catch:
      case Op_CatchProj:
      case Op_CProj:
      case Op_JumpProj:
      case Op_JProj:
      case Op_NeverBranch:
        set_dontcare(n);
        break;
      case Op_Jump:
1971
        mstack.push(n->in(1), Pre_Visit);     // Switch Value (could be shared)
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        mstack.push(n->in(0), Pre_Visit);     // Visit Control input
        continue;                             // while (mstack.is_nonempty())
      case Op_StrComp:
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      case Op_StrEquals:
      case Op_StrIndexOf:
1977
      case Op_AryEq:
1978
      case Op_EncodeISOArray:
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        set_shared(n); // Force result into register (it will be anyways)
        break;
      case Op_ConP: {  // Convert pointers above the centerline to NUL
        TypeNode *tn = n->as_Type(); // Constants derive from type nodes
        const TypePtr* tp = tn->type()->is_ptr();
        if (tp->_ptr == TypePtr::AnyNull) {
          tn->set_type(TypePtr::NULL_PTR);
        }
        break;
      }
1989 1990
      case Op_ConN: {  // Convert narrow pointers above the centerline to NUL
        TypeNode *tn = n->as_Type(); // Constants derive from type nodes
1991 1992
        const TypePtr* tp = tn->type()->make_ptr();
        if (tp && tp->_ptr == TypePtr::AnyNull) {
1993 1994 1995 1996
          tn->set_type(TypeNarrowOop::NULL_PTR);
        }
        break;
      }
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      case Op_Binary:         // These are introduced in the Post_Visit state.
        ShouldNotReachHere();
        break;
      case Op_ClearArray:
      case Op_SafePoint:
        mem_op = true;
        break;
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014
      default:
        if( n->is_Store() ) {
          // Do match stores, despite no ideal reg
          mem_op = true;
          break;
        }
        if( n->is_Mem() ) { // Loads and LoadStores
          mem_op = true;
          // Loads must be root of match tree due to prior load conflict
          if( C->subsume_loads() == false )
            set_shared(n);
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        }
        // Fall into default case
        if( !n->ideal_reg() )
          set_dontcare(n);  // Unmatchable Nodes
      } // end_switch

      for(int i = n->req() - 1; i >= 0; --i) { // For my children
        Node *m = n->in(i); // Get ith input
        if (m == NULL) continue;  // Ignore NULLs
        uint mop = m->Opcode();

        // Must clone all producers of flags, or we will not match correctly.
        // Suppose a compare setting int-flags is shared (e.g., a switch-tree)
        // then it will match into an ideal Op_RegFlags.  Alas, the fp-flags
        // are also there, so we may match a float-branch to int-flags and
        // expect the allocator to haul the flags from the int-side to the
        // fp-side.  No can do.
        if( _must_clone[mop] ) {
          mstack.push(m, Visit);
          continue; // for(int i = ...)
        }

2037
        if( mop == Op_AddP && m->in(AddPNode::Base)->is_DecodeNarrowPtr()) {
2038 2039 2040 2041 2042
          // Bases used in addresses must be shared but since
          // they are shared through a DecodeN they may appear
          // to have a single use so force sharing here.
          set_shared(m->in(AddPNode::Base)->in(1));
        }
2043

2044 2045
        // Clone addressing expressions as they are "free" in memory access instructions
        if( mem_op && i == MemNode::Address && mop == Op_AddP ) {
2046 2047 2048 2049 2050 2051
          // Some inputs for address expression are not put on stack
          // to avoid marking them as shared and forcing them into register
          // if they are used only in address expressions.
          // But they should be marked as shared if there are other uses
          // besides address expressions.

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          Node *off = m->in(AddPNode::Offset);
2053 2054 2055 2056 2057
          if( off->is_Con() &&
              // When there are other uses besides address expressions
              // put it on stack and mark as shared.
              !is_visited(m) ) {
            address_visited.test_set(m->_idx); // Flag as address_visited
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            Node *adr = m->in(AddPNode::Address);

            // Intel, ARM and friends can handle 2 adds in addressing mode
2061
            if( clone_shift_expressions && adr->is_AddP() &&
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                // AtomicAdd is not an addressing expression.
                // Cheap to find it by looking for screwy base.
2064 2065 2066 2067
                !adr->in(AddPNode::Base)->is_top() &&
                // Are there other uses besides address expressions?
                !is_visited(adr) ) {
              address_visited.set(adr->_idx); // Flag as address_visited
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              Node *shift = adr->in(AddPNode::Offset);
              // Check for shift by small constant as well
              if( shift->Opcode() == Op_LShiftX && shift->in(2)->is_Con() &&
2071 2072 2073 2074
                  shift->in(2)->get_int() <= 3 &&
                  // Are there other uses besides address expressions?
                  !is_visited(shift) ) {
                address_visited.set(shift->_idx); // Flag as address_visited
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                mstack.push(shift->in(2), Visit);
2076
                Node *conv = shift->in(1);
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#ifdef _LP64
                // Allow Matcher to match the rule which bypass
                // ConvI2L operation for an array index on LP64
                // if the index value is positive.
2081 2082 2083 2084 2085 2086
                if( conv->Opcode() == Op_ConvI2L &&
                    conv->as_Type()->type()->is_long()->_lo >= 0 &&
                    // Are there other uses besides address expressions?
                    !is_visited(conv) ) {
                  address_visited.set(conv->_idx); // Flag as address_visited
                  mstack.push(conv->in(1), Pre_Visit);
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                } else
#endif
2089
                mstack.push(conv, Pre_Visit);
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              } else {
                mstack.push(shift, Pre_Visit);
              }
              mstack.push(adr->in(AddPNode::Address), Pre_Visit);
              mstack.push(adr->in(AddPNode::Base), Pre_Visit);
            } else {  // Sparc, Alpha, PPC and friends
              mstack.push(adr, Pre_Visit);
            }

            // Clone X+offset as it also folds into most addressing expressions
            mstack.push(off, Visit);
            mstack.push(m->in(AddPNode::Base), Pre_Visit);
            continue; // for(int i = ...)
          } // if( off->is_Con() )
        }   // if( mem_op &&
        mstack.push(m, Pre_Visit);
      }     // for(int i = ...)
    }
    else if (nstate == Alt_Post_Visit) {
      mstack.pop(); // Remove node from stack
      // We cannot remove the Cmp input from the Bool here, as the Bool may be
      // shared and all users of the Bool need to move the Cmp in parallel.
      // This leaves both the Bool and the If pointing at the Cmp.  To
      // prevent the Matcher from trying to Match the Cmp along both paths
      // BoolNode::match_edge always returns a zero.

      // We reorder the Op_If in a pre-order manner, so we can visit without
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      // accidentally sharing the Cmp (the Bool and the If make 2 users).
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      n->add_req( n->in(1)->in(1) ); // Add the Cmp next to the Bool
    }
    else if (nstate == Post_Visit) {
      mstack.pop(); // Remove node from stack

      // Now hack a few special opcodes
      switch( n->Opcode() ) {       // Handle some opcodes special
      case Op_StorePConditional:
2126
      case Op_StoreIConditional:
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      case Op_StoreLConditional:
      case Op_CompareAndSwapI:
      case Op_CompareAndSwapL:
2130 2131
      case Op_CompareAndSwapP:
      case Op_CompareAndSwapN: {   // Convert trinary to binary-tree
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        Node *newval = n->in(MemNode::ValueIn );
2133
        Node *oldval  = n->in(LoadStoreConditionalNode::ExpectedIn);
2134
        Node *pair = new (C) BinaryNode( oldval, newval );
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        n->set_req(MemNode::ValueIn,pair);
2136
        n->del_req(LoadStoreConditionalNode::ExpectedIn);
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        break;
      }
      case Op_CMoveD:              // Convert trinary to binary-tree
      case Op_CMoveF:
      case Op_CMoveI:
      case Op_CMoveL:
2143
      case Op_CMoveN:
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      case Op_CMoveP: {
        // Restructure into a binary tree for Matching.  It's possible that
        // we could move this code up next to the graph reshaping for IfNodes
        // or vice-versa, but I do not want to debug this for Ladybird.
        // 10/2/2000 CNC.
2149
        Node *pair1 = new (C) BinaryNode(n->in(1),n->in(1)->in(1));
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        n->set_req(1,pair1);
2151
        Node *pair2 = new (C) BinaryNode(n->in(2),n->in(3));
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        n->set_req(2,pair2);
        n->del_req(3);
        break;
      }
2156
      case Op_LoopLimit: {
2157
        Node *pair1 = new (C) BinaryNode(n->in(1),n->in(2));
2158 2159 2160 2161 2162
        n->set_req(1,pair1);
        n->set_req(2,n->in(3));
        n->del_req(3);
        break;
      }
2163
      case Op_StrEquals: {
2164
        Node *pair1 = new (C) BinaryNode(n->in(2),n->in(3));
2165 2166 2167 2168 2169 2170 2171
        n->set_req(2,pair1);
        n->set_req(3,n->in(4));
        n->del_req(4);
        break;
      }
      case Op_StrComp:
      case Op_StrIndexOf: {
2172
        Node *pair1 = new (C) BinaryNode(n->in(2),n->in(3));
2173
        n->set_req(2,pair1);
2174
        Node *pair2 = new (C) BinaryNode(n->in(4),n->in(5));
2175 2176 2177 2178
        n->set_req(3,pair2);
        n->del_req(5);
        n->del_req(4);
        break;
2179 2180 2181 2182 2183 2184 2185
      }
      case Op_EncodeISOArray: {
        // Restructure into a binary tree for Matching.
        Node* pair = new (C) BinaryNode(n->in(3), n->in(4));
        n->set_req(3, pair);
        n->del_req(4);
        break;
2186
      }
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      default:
        break;
      }
    }
    else {
      ShouldNotReachHere();
    }
  } // end of while (mstack.is_nonempty())
}

#ifdef ASSERT
// machine-independent root to machine-dependent root
void Matcher::dump_old2new_map() {
  _old2new_map.dump();
}
#endif

//---------------------------collect_null_checks-------------------------------
// Find null checks in the ideal graph; write a machine-specific node for
// it.  Used by later implicit-null-check handling.  Actually collects
// either an IfTrue or IfFalse for the common NOT-null path, AND the ideal
// value being tested.
2209
void Matcher::collect_null_checks( Node *proj, Node *orig_proj ) {
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  Node *iff = proj->in(0);
  if( iff->Opcode() == Op_If ) {
    // During matching If's have Bool & Cmp side-by-side
    BoolNode *b = iff->in(1)->as_Bool();
    Node *cmp = iff->in(2);
2215 2216 2217 2218 2219 2220 2221
    int opc = cmp->Opcode();
    if (opc != Op_CmpP && opc != Op_CmpN) return;

    const Type* ct = cmp->in(2)->bottom_type();
    if (ct == TypePtr::NULL_PTR ||
        (opc == Op_CmpN && ct == TypeNarrowOop::NULL_PTR)) {

2222
      bool push_it = false;
2223 2224 2225 2226
      if( proj->Opcode() == Op_IfTrue ) {
        extern int all_null_checks_found;
        all_null_checks_found++;
        if( b->_test._test == BoolTest::ne ) {
2227
          push_it = true;
2228 2229 2230 2231
        }
      } else {
        assert( proj->Opcode() == Op_IfFalse, "" );
        if( b->_test._test == BoolTest::eq ) {
2232
          push_it = true;
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        }
      }
2235 2236 2237 2238
      if( push_it ) {
        _null_check_tests.push(proj);
        Node* val = cmp->in(1);
#ifdef _LP64
2239 2240
        if (val->bottom_type()->isa_narrowoop() &&
            !Matcher::narrow_oop_use_complex_address()) {
2241 2242 2243 2244 2245 2246 2247 2248 2249 2250 2251 2252 2253 2254 2255
          //
          // Look for DecodeN node which should be pinned to orig_proj.
          // On platforms (Sparc) which can not handle 2 adds
          // in addressing mode we have to keep a DecodeN node and
          // use it to do implicit NULL check in address.
          //
          // DecodeN node was pinned to non-null path (orig_proj) during
          // CastPP transformation in final_graph_reshaping_impl().
          //
          uint cnt = orig_proj->outcnt();
          for (uint i = 0; i < orig_proj->outcnt(); i++) {
            Node* d = orig_proj->raw_out(i);
            if (d->is_DecodeN() && d->in(1) == val) {
              val = d;
              val->set_req(0, NULL); // Unpin now.
2256 2257 2258
              // Mark this as special case to distinguish from
              // a regular case: CmpP(DecodeN, NULL).
              val = (Node*)(((intptr_t)val) | 1);
2259 2260 2261 2262 2263 2264 2265
              break;
            }
          }
        }
#endif
        _null_check_tests.push(val);
      }
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    }
  }
}

//---------------------------validate_null_checks------------------------------
// Its possible that the value being NULL checked is not the root of a match
// tree.  If so, I cannot use the value in an implicit null check.
void Matcher::validate_null_checks( ) {
  uint cnt = _null_check_tests.size();
  for( uint i=0; i < cnt; i+=2 ) {
    Node *test = _null_check_tests[i];
    Node *val = _null_check_tests[i+1];
2278 2279
    bool is_decoden = ((intptr_t)val) & 1;
    val = (Node*)(((intptr_t)val) & ~1);
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2280
    if (has_new_node(val)) {
2281 2282
      Node* new_val = new_node(val);
      if (is_decoden) {
2283
        assert(val->is_DecodeNarrowPtr() && val->in(0) == NULL, "sanity");
2284 2285 2286 2287 2288 2289 2290
        // Note: new_val may have a control edge if
        // the original ideal node DecodeN was matched before
        // it was unpinned in Matcher::collect_null_checks().
        // Unpin the mach node and mark it.
        new_val->set_req(0, NULL);
        new_val = (Node*)(((intptr_t)new_val) | 1);
      }
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      // Is a match-tree root, so replace with the matched value
2292
      _null_check_tests.map(i+1, new_val);
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2293 2294 2295 2296 2297 2298 2299 2300 2301 2302 2303 2304 2305 2306 2307
    } else {
      // Yank from candidate list
      _null_check_tests.map(i+1,_null_check_tests[--cnt]);
      _null_check_tests.map(i,_null_check_tests[--cnt]);
      _null_check_tests.pop();
      _null_check_tests.pop();
      i-=2;
    }
  }
}

// Used by the DFA in dfa_xxx.cpp.  Check for a following barrier or
// atomic instruction acting as a store_load barrier without any
// intervening volatile load, and thus we don't need a barrier here.
// We retain the Node to act as a compiler ordering barrier.
2308 2309 2310 2311 2312 2313 2314 2315 2316 2317 2318 2319 2320 2321
bool Matcher::post_store_load_barrier(const Node* vmb) {
  Compile* C = Compile::current();
  assert(vmb->is_MemBar(), "");
  assert(vmb->Opcode() != Op_MemBarAcquire, "");
  const MemBarNode* membar = vmb->as_MemBar();

  // Get the Ideal Proj node, ctrl, that can be used to iterate forward
  Node* ctrl = NULL;
  for (DUIterator_Fast imax, i = membar->fast_outs(imax); i < imax; i++) {
    Node* p = membar->fast_out(i);
    assert(p->is_Proj(), "only projections here");
    if ((p->as_Proj()->_con == TypeFunc::Control) &&
        !C->node_arena()->contains(p)) { // Unmatched old-space only
      ctrl = p;
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      break;
2323
    }
D
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2324
  }
2325
  assert((ctrl != NULL), "missing control projection");
D
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2326

2327
  for (DUIterator_Fast jmax, j = ctrl->fast_outs(jmax); j < jmax; j++) {
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2328 2329 2330 2331 2332 2333 2334 2335 2336 2337 2338 2339 2340
    Node *x = ctrl->fast_out(j);
    int xop = x->Opcode();

    // We don't need current barrier if we see another or a lock
    // before seeing volatile load.
    //
    // Op_Fastunlock previously appeared in the Op_* list below.
    // With the advent of 1-0 lock operations we're no longer guaranteed
    // that a monitor exit operation contains a serializing instruction.

    if (xop == Op_MemBarVolatile ||
        xop == Op_CompareAndSwapL ||
        xop == Op_CompareAndSwapP ||
2341
        xop == Op_CompareAndSwapN ||
2342
        xop == Op_CompareAndSwapI) {
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2343
      return true;
2344 2345 2346 2347 2348 2349 2350 2351
    }

    // Op_FastLock previously appeared in the Op_* list above.
    // With biased locking we're no longer guaranteed that a monitor
    // enter operation contains a serializing instruction.
    if ((xop == Op_FastLock) && !UseBiasedLocking) {
      return true;
    }
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2352 2353 2354

    if (x->is_MemBar()) {
      // We must retain this membar if there is an upcoming volatile
2355 2356
      // load, which will be followed by acquire membar.
      if (xop == Op_MemBarAcquire) {
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2357
        return false;
2358 2359 2360 2361 2362
      } else {
        // For other kinds of barriers, check by pretending we
        // are them, and seeing if we can be removed.
        return post_store_load_barrier(x->as_MemBar());
      }
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2363 2364 2365
    }

    // probably not necessary to check for these
2366
    if (x->is_Call() || x->is_SafePoint() || x->is_block_proj()) {
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      return false;
2368
    }
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2369 2370 2371 2372 2373 2374 2375 2376 2377 2378 2379 2380 2381 2382 2383 2384 2385 2386 2387 2388 2389 2390 2391 2392 2393 2394 2395 2396 2397 2398 2399 2400 2401 2402 2403 2404 2405 2406 2407 2408 2409 2410 2411 2412 2413 2414 2415 2416 2417 2418 2419 2420 2421 2422 2423 2424 2425
  }
  return false;
}

//=============================================================================
//---------------------------State---------------------------------------------
State::State(void) {
#ifdef ASSERT
  _id = 0;
  _kids[0] = _kids[1] = (State*)(intptr_t) CONST64(0xcafebabecafebabe);
  _leaf = (Node*)(intptr_t) CONST64(0xbaadf00dbaadf00d);
  //memset(_cost, -1, sizeof(_cost));
  //memset(_rule, -1, sizeof(_rule));
#endif
  memset(_valid, 0, sizeof(_valid));
}

#ifdef ASSERT
State::~State() {
  _id = 99;
  _kids[0] = _kids[1] = (State*)(intptr_t) CONST64(0xcafebabecafebabe);
  _leaf = (Node*)(intptr_t) CONST64(0xbaadf00dbaadf00d);
  memset(_cost, -3, sizeof(_cost));
  memset(_rule, -3, sizeof(_rule));
}
#endif

#ifndef PRODUCT
//---------------------------dump----------------------------------------------
void State::dump() {
  tty->print("\n");
  dump(0);
}

void State::dump(int depth) {
  for( int j = 0; j < depth; j++ )
    tty->print("   ");
  tty->print("--N: ");
  _leaf->dump();
  uint i;
  for( i = 0; i < _LAST_MACH_OPER; i++ )
    // Check for valid entry
    if( valid(i) ) {
      for( int j = 0; j < depth; j++ )
        tty->print("   ");
        assert(_cost[i] != max_juint, "cost must be a valid value");
        assert(_rule[i] < _last_Mach_Node, "rule[i] must be valid rule");
        tty->print_cr("%s  %d  %s",
                      ruleName[i], _cost[i], ruleName[_rule[i]] );
      }
  tty->print_cr("");

  for( i=0; i<2; i++ )
    if( _kids[i] )
      _kids[i]->dump(depth+1);
}
#endif