macro.cpp 79.2 KB
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/*
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 * Copyright 2005-2008 Sun Microsystems, Inc.  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.
 *
 * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
 * CA 95054 USA or visit www.sun.com if you need additional information or
 * have any questions.
 *
 */

#include "incls/_precompiled.incl"
#include "incls/_macro.cpp.incl"


//
// Replace any references to "oldref" in inputs to "use" with "newref".
// Returns the number of replacements made.
//
int PhaseMacroExpand::replace_input(Node *use, Node *oldref, Node *newref) {
  int nreplacements = 0;
  uint req = use->req();
  for (uint j = 0; j < use->len(); j++) {
    Node *uin = use->in(j);
    if (uin == oldref) {
      if (j < req)
        use->set_req(j, newref);
      else
        use->set_prec(j, newref);
      nreplacements++;
    } else if (j >= req && uin == NULL) {
      break;
    }
  }
  return nreplacements;
}

void PhaseMacroExpand::copy_call_debug_info(CallNode *oldcall, CallNode * newcall) {
  // Copy debug information and adjust JVMState information
  uint old_dbg_start = oldcall->tf()->domain()->cnt();
  uint new_dbg_start = newcall->tf()->domain()->cnt();
  int jvms_adj  = new_dbg_start - old_dbg_start;
  assert (new_dbg_start == newcall->req(), "argument count mismatch");
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  Dict* sosn_map = new Dict(cmpkey,hashkey);
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  for (uint i = old_dbg_start; i < oldcall->req(); i++) {
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    Node* old_in = oldcall->in(i);
    // Clone old SafePointScalarObjectNodes, adjusting their field contents.
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    if (old_in != NULL && old_in->is_SafePointScalarObject()) {
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      SafePointScalarObjectNode* old_sosn = old_in->as_SafePointScalarObject();
      uint old_unique = C->unique();
      Node* new_in = old_sosn->clone(jvms_adj, sosn_map);
      if (old_unique != C->unique()) {
        new_in = transform_later(new_in); // Register new node.
      }
      old_in = new_in;
    }
    newcall->add_req(old_in);
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  }
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  newcall->set_jvms(oldcall->jvms());
  for (JVMState *jvms = newcall->jvms(); jvms != NULL; jvms = jvms->caller()) {
    jvms->set_map(newcall);
    jvms->set_locoff(jvms->locoff()+jvms_adj);
    jvms->set_stkoff(jvms->stkoff()+jvms_adj);
    jvms->set_monoff(jvms->monoff()+jvms_adj);
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    jvms->set_scloff(jvms->scloff()+jvms_adj);
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    jvms->set_endoff(jvms->endoff()+jvms_adj);
  }
}

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Node* PhaseMacroExpand::opt_bits_test(Node* ctrl, Node* region, int edge, Node* word, int mask, int bits, bool return_fast_path) {
  Node* cmp;
  if (mask != 0) {
    Node* and_node = transform_later(new (C, 3) AndXNode(word, MakeConX(mask)));
    cmp = transform_later(new (C, 3) CmpXNode(and_node, MakeConX(bits)));
  } else {
    cmp = word;
  }
  Node* bol = transform_later(new (C, 2) BoolNode(cmp, BoolTest::ne));
  IfNode* iff = new (C, 2) IfNode( ctrl, bol, PROB_MIN, COUNT_UNKNOWN );
  transform_later(iff);
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  // Fast path taken.
  Node *fast_taken = transform_later( new (C, 1) IfFalseNode(iff) );
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  // Fast path not-taken, i.e. slow path
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  Node *slow_taken = transform_later( new (C, 1) IfTrueNode(iff) );

  if (return_fast_path) {
    region->init_req(edge, slow_taken); // Capture slow-control
    return fast_taken;
  } else {
    region->init_req(edge, fast_taken); // Capture fast-control
    return slow_taken;
  }
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}

//--------------------copy_predefined_input_for_runtime_call--------------------
void PhaseMacroExpand::copy_predefined_input_for_runtime_call(Node * ctrl, CallNode* oldcall, CallNode* call) {
  // Set fixed predefined input arguments
  call->init_req( TypeFunc::Control, ctrl );
  call->init_req( TypeFunc::I_O    , oldcall->in( TypeFunc::I_O) );
  call->init_req( TypeFunc::Memory , oldcall->in( TypeFunc::Memory ) ); // ?????
  call->init_req( TypeFunc::ReturnAdr, oldcall->in( TypeFunc::ReturnAdr ) );
  call->init_req( TypeFunc::FramePtr, oldcall->in( TypeFunc::FramePtr ) );
}

//------------------------------make_slow_call---------------------------------
CallNode* PhaseMacroExpand::make_slow_call(CallNode *oldcall, const TypeFunc* slow_call_type, address slow_call, const char* leaf_name, Node* slow_path, Node* parm0, Node* parm1) {

  // Slow-path call
  int size = slow_call_type->domain()->cnt();
 CallNode *call = leaf_name
   ? (CallNode*)new (C, size) CallLeafNode      ( slow_call_type, slow_call, leaf_name, TypeRawPtr::BOTTOM )
   : (CallNode*)new (C, size) CallStaticJavaNode( slow_call_type, slow_call, OptoRuntime::stub_name(slow_call), oldcall->jvms()->bci(), TypeRawPtr::BOTTOM );

  // Slow path call has no side-effects, uses few values
  copy_predefined_input_for_runtime_call(slow_path, oldcall, call );
  if (parm0 != NULL)  call->init_req(TypeFunc::Parms+0, parm0);
  if (parm1 != NULL)  call->init_req(TypeFunc::Parms+1, parm1);
  copy_call_debug_info(oldcall, call);
  call->set_cnt(PROB_UNLIKELY_MAG(4));  // Same effect as RC_UNCOMMON.
  _igvn.hash_delete(oldcall);
  _igvn.subsume_node(oldcall, call);
  transform_later(call);

  return call;
}

void PhaseMacroExpand::extract_call_projections(CallNode *call) {
  _fallthroughproj = NULL;
  _fallthroughcatchproj = NULL;
  _ioproj_fallthrough = NULL;
  _ioproj_catchall = NULL;
  _catchallcatchproj = NULL;
  _memproj_fallthrough = NULL;
  _memproj_catchall = NULL;
  _resproj = NULL;
  for (DUIterator_Fast imax, i = call->fast_outs(imax); i < imax; i++) {
    ProjNode *pn = call->fast_out(i)->as_Proj();
    switch (pn->_con) {
      case TypeFunc::Control:
      {
        // For Control (fallthrough) and I_O (catch_all_index) we have CatchProj -> Catch -> Proj
        _fallthroughproj = pn;
        DUIterator_Fast jmax, j = pn->fast_outs(jmax);
        const Node *cn = pn->fast_out(j);
        if (cn->is_Catch()) {
          ProjNode *cpn = NULL;
          for (DUIterator_Fast kmax, k = cn->fast_outs(kmax); k < kmax; k++) {
            cpn = cn->fast_out(k)->as_Proj();
            assert(cpn->is_CatchProj(), "must be a CatchProjNode");
            if (cpn->_con == CatchProjNode::fall_through_index)
              _fallthroughcatchproj = cpn;
            else {
              assert(cpn->_con == CatchProjNode::catch_all_index, "must be correct index.");
              _catchallcatchproj = cpn;
            }
          }
        }
        break;
      }
      case TypeFunc::I_O:
        if (pn->_is_io_use)
          _ioproj_catchall = pn;
        else
          _ioproj_fallthrough = pn;
        break;
      case TypeFunc::Memory:
        if (pn->_is_io_use)
          _memproj_catchall = pn;
        else
          _memproj_fallthrough = pn;
        break;
      case TypeFunc::Parms:
        _resproj = pn;
        break;
      default:
        assert(false, "unexpected projection from allocation node.");
    }
  }

}

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// Eliminate a card mark sequence.  p2x is a ConvP2XNode
void PhaseMacroExpand::eliminate_card_mark(Node *p2x) {
  assert(p2x->Opcode() == Op_CastP2X, "ConvP2XNode required");
  Node *shift = p2x->unique_out();
  Node *addp = shift->unique_out();
  for (DUIterator_Last jmin, j = addp->last_outs(jmin); j >= jmin; --j) {
    Node *st = addp->last_out(j);
    assert(st->is_Store(), "store required");
    _igvn.replace_node(st, st->in(MemNode::Memory));
  }
}

// Search for a memory operation for the specified memory slice.
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static Node *scan_mem_chain(Node *mem, int alias_idx, int offset, Node *start_mem, Node *alloc, PhaseGVN *phase) {
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  Node *orig_mem = mem;
  Node *alloc_mem = alloc->in(TypeFunc::Memory);
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  const TypeOopPtr *tinst = phase->C->get_adr_type(alias_idx)->isa_oopptr();
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  while (true) {
    if (mem == alloc_mem || mem == start_mem ) {
      return mem;  // hit one of our sentinals
    } else if (mem->is_MergeMem()) {
      mem = mem->as_MergeMem()->memory_at(alias_idx);
    } else if (mem->is_Proj() && mem->as_Proj()->_con == TypeFunc::Memory) {
      Node *in = mem->in(0);
      // we can safely skip over safepoints, calls, locks and membars because we
      // already know that the object is safe to eliminate.
      if (in->is_Initialize() && in->as_Initialize()->allocation() == alloc) {
        return in;
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      } else if (in->is_Call()) {
        CallNode *call = in->as_Call();
        if (!call->may_modify(tinst, phase)) {
          mem = call->in(TypeFunc::Memory);
        }
        mem = in->in(TypeFunc::Memory);
      } else if (in->is_MemBar()) {
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        mem = in->in(TypeFunc::Memory);
      } else {
        assert(false, "unexpected projection");
      }
    } else if (mem->is_Store()) {
      const TypePtr* atype = mem->as_Store()->adr_type();
      int adr_idx = Compile::current()->get_alias_index(atype);
      if (adr_idx == alias_idx) {
        assert(atype->isa_oopptr(), "address type must be oopptr");
        int adr_offset = atype->offset();
        uint adr_iid = atype->is_oopptr()->instance_id();
        // Array elements references have the same alias_idx
        // but different offset and different instance_id.
        if (adr_offset == offset && adr_iid == alloc->_idx)
          return mem;
      } else {
        assert(adr_idx == Compile::AliasIdxRaw, "address must match or be raw");
      }
      mem = mem->in(MemNode::Memory);
    } else {
      return mem;
    }
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    assert(mem != orig_mem, "dead memory loop");
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  }
}

//
// Given a Memory Phi, compute a value Phi containing the values from stores
// on the input paths.
// Note: this function is recursive, its depth is limied by the "level" argument
// Returns the computed Phi, or NULL if it cannot compute it.
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Node *PhaseMacroExpand::value_from_mem_phi(Node *mem, BasicType ft, const Type *phi_type, const TypeOopPtr *adr_t, Node *alloc, Node_Stack *value_phis, int level) {
  assert(mem->is_Phi(), "sanity");
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  int alias_idx = C->get_alias_index(adr_t);
  int offset = adr_t->offset();
  int instance_id = adr_t->instance_id();

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  // Check if an appropriate value phi already exists.
  Node* region = mem->in(0);
  for (DUIterator_Fast kmax, k = region->fast_outs(kmax); k < kmax; k++) {
    Node* phi = region->fast_out(k);
    if (phi->is_Phi() && phi != mem &&
        phi->as_Phi()->is_same_inst_field(phi_type, instance_id, alias_idx, offset)) {
      return phi;
    }
  }
  // Check if an appropriate new value phi already exists.
  Node* new_phi = NULL;
  uint size = value_phis->size();
  for (uint i=0; i < size; i++) {
    if ( mem->_idx == value_phis->index_at(i) ) {
      return value_phis->node_at(i);
    }
  }

  if (level <= 0) {
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    return NULL; // Give up: phi tree too deep
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  }
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  Node *start_mem = C->start()->proj_out(TypeFunc::Memory);
  Node *alloc_mem = alloc->in(TypeFunc::Memory);

  uint length = mem->req();
  GrowableArray <Node *> values(length, length, NULL);

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  // create a new Phi for the value
  PhiNode *phi = new (C, length) PhiNode(mem->in(0), phi_type, NULL, instance_id, alias_idx, offset);
  transform_later(phi);
  value_phis->push(phi, mem->_idx);

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  for (uint j = 1; j < length; j++) {
    Node *in = mem->in(j);
    if (in == NULL || in->is_top()) {
      values.at_put(j, in);
    } else  {
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      Node *val = scan_mem_chain(in, alias_idx, offset, start_mem, alloc, &_igvn);
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      if (val == start_mem || val == alloc_mem) {
        // hit a sentinel, return appropriate 0 value
        values.at_put(j, _igvn.zerocon(ft));
        continue;
      }
      if (val->is_Initialize()) {
        val = val->as_Initialize()->find_captured_store(offset, type2aelembytes(ft), &_igvn);
      }
      if (val == NULL) {
        return NULL;  // can't find a value on this path
      }
      if (val == mem) {
        values.at_put(j, mem);
      } else if (val->is_Store()) {
        values.at_put(j, val->in(MemNode::ValueIn));
      } else if(val->is_Proj() && val->in(0) == alloc) {
        values.at_put(j, _igvn.zerocon(ft));
      } else if (val->is_Phi()) {
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        val = value_from_mem_phi(val, ft, phi_type, adr_t, alloc, value_phis, level-1);
        if (val == NULL) {
          return NULL;
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        }
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        values.at_put(j, val);
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      } else {
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        assert(false, "unknown node on this path");
        return NULL;  // unknown node on this path
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      }
    }
  }
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  // Set Phi's inputs
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  for (uint j = 1; j < length; j++) {
    if (values.at(j) == mem) {
      phi->init_req(j, phi);
    } else {
      phi->init_req(j, values.at(j));
    }
  }
  return phi;
}

// Search the last value stored into the object's field.
Node *PhaseMacroExpand::value_from_mem(Node *sfpt_mem, BasicType ft, const Type *ftype, const TypeOopPtr *adr_t, Node *alloc) {
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  assert(adr_t->is_known_instance_field(), "instance required");
  int instance_id = adr_t->instance_id();
  assert((uint)instance_id == alloc->_idx, "wrong allocation");
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  int alias_idx = C->get_alias_index(adr_t);
  int offset = adr_t->offset();
  Node *start_mem = C->start()->proj_out(TypeFunc::Memory);
  Node *alloc_ctrl = alloc->in(TypeFunc::Control);
  Node *alloc_mem = alloc->in(TypeFunc::Memory);
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  Arena *a = Thread::current()->resource_area();
  VectorSet visited(a);
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  bool done = sfpt_mem == alloc_mem;
  Node *mem = sfpt_mem;
  while (!done) {
    if (visited.test_set(mem->_idx)) {
      return NULL;  // found a loop, give up
    }
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    mem = scan_mem_chain(mem, alias_idx, offset, start_mem, alloc, &_igvn);
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    if (mem == start_mem || mem == alloc_mem) {
      done = true;  // hit a sentinel, return appropriate 0 value
    } else if (mem->is_Initialize()) {
      mem = mem->as_Initialize()->find_captured_store(offset, type2aelembytes(ft), &_igvn);
      if (mem == NULL) {
        done = true; // Something go wrong.
      } else if (mem->is_Store()) {
        const TypePtr* atype = mem->as_Store()->adr_type();
        assert(C->get_alias_index(atype) == Compile::AliasIdxRaw, "store is correct memory slice");
        done = true;
      }
    } else if (mem->is_Store()) {
      const TypeOopPtr* atype = mem->as_Store()->adr_type()->isa_oopptr();
      assert(atype != NULL, "address type must be oopptr");
      assert(C->get_alias_index(atype) == alias_idx &&
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             atype->is_known_instance_field() && atype->offset() == offset &&
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             atype->instance_id() == instance_id, "store is correct memory slice");
      done = true;
    } else if (mem->is_Phi()) {
      // try to find a phi's unique input
      Node *unique_input = NULL;
      Node *top = C->top();
      for (uint i = 1; i < mem->req(); i++) {
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        Node *n = scan_mem_chain(mem->in(i), alias_idx, offset, start_mem, alloc, &_igvn);
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        if (n == NULL || n == top || n == mem) {
          continue;
        } else if (unique_input == NULL) {
          unique_input = n;
        } else if (unique_input != n) {
          unique_input = top;
          break;
        }
      }
      if (unique_input != NULL && unique_input != top) {
        mem = unique_input;
      } else {
        done = true;
      }
    } else {
      assert(false, "unexpected node");
    }
  }
  if (mem != NULL) {
    if (mem == start_mem || mem == alloc_mem) {
      // hit a sentinel, return appropriate 0 value
      return _igvn.zerocon(ft);
    } else if (mem->is_Store()) {
      return mem->in(MemNode::ValueIn);
    } else if (mem->is_Phi()) {
      // attempt to produce a Phi reflecting the values on the input paths of the Phi
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      Node_Stack value_phis(a, 8);
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      Node * phi = value_from_mem_phi(mem, ft, ftype, adr_t, alloc, &value_phis, ValueSearchLimit);
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      if (phi != NULL) {
        return phi;
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      } else {
        // Kill all new Phis
        while(value_phis.is_nonempty()) {
          Node* n = value_phis.node();
          _igvn.hash_delete(n);
          _igvn.subsume_node(n, C->top());
          value_phis.pop();
        }
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      }
    }
  }
  // Something go wrong.
  return NULL;
}

// Check the possibility of scalar replacement.
bool PhaseMacroExpand::can_eliminate_allocation(AllocateNode *alloc, GrowableArray <SafePointNode *>& safepoints) {
  //  Scan the uses of the allocation to check for anything that would
  //  prevent us from eliminating it.
  NOT_PRODUCT( const char* fail_eliminate = NULL; )
  DEBUG_ONLY( Node* disq_node = NULL; )
  bool  can_eliminate = true;

  Node* res = alloc->result_cast();
  const TypeOopPtr* res_type = NULL;
  if (res == NULL) {
    // All users were eliminated.
  } else if (!res->is_CheckCastPP()) {
    alloc->_is_scalar_replaceable = false;  // don't try again
    NOT_PRODUCT(fail_eliminate = "Allocation does not have unique CheckCastPP";)
    can_eliminate = false;
  } else {
    res_type = _igvn.type(res)->isa_oopptr();
    if (res_type == NULL) {
      NOT_PRODUCT(fail_eliminate = "Neither instance or array allocation";)
      can_eliminate = false;
    } else if (res_type->isa_aryptr()) {
      int length = alloc->in(AllocateNode::ALength)->find_int_con(-1);
      if (length < 0) {
        NOT_PRODUCT(fail_eliminate = "Array's size is not constant";)
        can_eliminate = false;
      }
    }
  }

  if (can_eliminate && res != NULL) {
    for (DUIterator_Fast jmax, j = res->fast_outs(jmax);
                               j < jmax && can_eliminate; j++) {
      Node* use = res->fast_out(j);

      if (use->is_AddP()) {
        const TypePtr* addp_type = _igvn.type(use)->is_ptr();
        int offset = addp_type->offset();

        if (offset == Type::OffsetTop || offset == Type::OffsetBot) {
          NOT_PRODUCT(fail_eliminate = "Undefined field referrence";)
          can_eliminate = false;
          break;
        }
        for (DUIterator_Fast kmax, k = use->fast_outs(kmax);
                                   k < kmax && can_eliminate; k++) {
          Node* n = use->fast_out(k);
          if (!n->is_Store() && n->Opcode() != Op_CastP2X) {
            DEBUG_ONLY(disq_node = n;)
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            if (n->is_Load() || n->is_LoadStore()) {
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              NOT_PRODUCT(fail_eliminate = "Field load";)
            } else {
              NOT_PRODUCT(fail_eliminate = "Not store field referrence";)
            }
            can_eliminate = false;
          }
        }
      } else if (use->is_SafePoint()) {
        SafePointNode* sfpt = use->as_SafePoint();
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        if (sfpt->is_Call() && sfpt->as_Call()->has_non_debug_use(res)) {
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          // Object is passed as argument.
          DEBUG_ONLY(disq_node = use;)
          NOT_PRODUCT(fail_eliminate = "Object is passed as argument";)
          can_eliminate = false;
        }
        Node* sfptMem = sfpt->memory();
        if (sfptMem == NULL || sfptMem->is_top()) {
          DEBUG_ONLY(disq_node = use;)
          NOT_PRODUCT(fail_eliminate = "NULL or TOP memory";)
          can_eliminate = false;
        } else {
          safepoints.append_if_missing(sfpt);
        }
      } else if (use->Opcode() != Op_CastP2X) { // CastP2X is used by card mark
        if (use->is_Phi()) {
          if (use->outcnt() == 1 && use->unique_out()->Opcode() == Op_Return) {
            NOT_PRODUCT(fail_eliminate = "Object is return value";)
          } else {
            NOT_PRODUCT(fail_eliminate = "Object is referenced by Phi";)
          }
          DEBUG_ONLY(disq_node = use;)
        } else {
          if (use->Opcode() == Op_Return) {
            NOT_PRODUCT(fail_eliminate = "Object is return value";)
          }else {
            NOT_PRODUCT(fail_eliminate = "Object is referenced by node";)
          }
          DEBUG_ONLY(disq_node = use;)
        }
        can_eliminate = false;
      }
    }
  }

#ifndef PRODUCT
  if (PrintEliminateAllocations) {
    if (can_eliminate) {
      tty->print("Scalar ");
      if (res == NULL)
        alloc->dump();
      else
        res->dump();
    } else {
      tty->print("NotScalar (%s)", fail_eliminate);
      if (res == NULL)
        alloc->dump();
      else
        res->dump();
#ifdef ASSERT
      if (disq_node != NULL) {
          tty->print("  >>>> ");
          disq_node->dump();
      }
#endif /*ASSERT*/
    }
  }
#endif
  return can_eliminate;
}

// Do scalar replacement.
bool PhaseMacroExpand::scalar_replacement(AllocateNode *alloc, GrowableArray <SafePointNode *>& safepoints) {
  GrowableArray <SafePointNode *> safepoints_done;

  ciKlass* klass = NULL;
  ciInstanceKlass* iklass = NULL;
  int nfields = 0;
  int array_base;
  int element_size;
  BasicType basic_elem_type;
  ciType* elem_type;

  Node* res = alloc->result_cast();
  const TypeOopPtr* res_type = NULL;
  if (res != NULL) { // Could be NULL when there are no users
    res_type = _igvn.type(res)->isa_oopptr();
  }

  if (res != NULL) {
    klass = res_type->klass();
    if (res_type->isa_instptr()) {
      // find the fields of the class which will be needed for safepoint debug information
      assert(klass->is_instance_klass(), "must be an instance klass.");
      iklass = klass->as_instance_klass();
      nfields = iklass->nof_nonstatic_fields();
    } else {
      // find the array's elements which will be needed for safepoint debug information
      nfields = alloc->in(AllocateNode::ALength)->find_int_con(-1);
      assert(klass->is_array_klass() && nfields >= 0, "must be an array klass.");
      elem_type = klass->as_array_klass()->element_type();
      basic_elem_type = elem_type->basic_type();
      array_base = arrayOopDesc::base_offset_in_bytes(basic_elem_type);
      element_size = type2aelembytes(basic_elem_type);
    }
  }
  //
  // Process the safepoint uses
  //
  while (safepoints.length() > 0) {
    SafePointNode* sfpt = safepoints.pop();
    Node* mem = sfpt->memory();
    uint first_ind = sfpt->req();
    SafePointScalarObjectNode* sobj = new (C, 1) SafePointScalarObjectNode(res_type,
#ifdef ASSERT
                                                 alloc,
#endif
                                                 first_ind, nfields);
    sobj->init_req(0, sfpt->in(TypeFunc::Control));
    transform_later(sobj);

    // Scan object's fields adding an input to the safepoint for each field.
    for (int j = 0; j < nfields; j++) {
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      intptr_t offset;
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      ciField* field = NULL;
      if (iklass != NULL) {
        field = iklass->nonstatic_field_at(j);
        offset = field->offset();
        elem_type = field->type();
        basic_elem_type = field->layout_type();
      } else {
620
        offset = array_base + j * (intptr_t)element_size;
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      }

      const Type *field_type;
      // The next code is taken from Parse::do_get_xxx().
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      if (basic_elem_type == T_OBJECT || basic_elem_type == T_ARRAY) {
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        if (!elem_type->is_loaded()) {
          field_type = TypeInstPtr::BOTTOM;
        } else if (field != NULL && field->is_constant()) {
          // This can happen if the constant oop is non-perm.
          ciObject* con = field->constant_value().as_object();
          // Do not "join" in the previous type; it doesn't add value,
          // and may yield a vacuous result if the field is of interface type.
          field_type = TypeOopPtr::make_from_constant(con)->isa_oopptr();
          assert(field_type != NULL, "field singleton type must be consistent");
        } else {
          field_type = TypeOopPtr::make_from_klass(elem_type->as_klass());
        }
638
        if (UseCompressedOops) {
639
          field_type = field_type->make_narrowoop();
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          basic_elem_type = T_NARROWOOP;
        }
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      } else {
        field_type = Type::get_const_basic_type(basic_elem_type);
      }

      const TypeOopPtr *field_addr_type = res_type->add_offset(offset)->isa_oopptr();

      Node *field_val = value_from_mem(mem, basic_elem_type, field_type, field_addr_type, alloc);
      if (field_val == NULL) {
        // we weren't able to find a value for this field,
        // give up on eliminating this allocation
        alloc->_is_scalar_replaceable = false;  // don't try again
        // remove any extra entries we added to the safepoint
        uint last = sfpt->req() - 1;
        for (int k = 0;  k < j; k++) {
          sfpt->del_req(last--);
        }
        // rollback processed safepoints
        while (safepoints_done.length() > 0) {
          SafePointNode* sfpt_done = safepoints_done.pop();
          // remove any extra entries we added to the safepoint
          last = sfpt_done->req() - 1;
          for (int k = 0;  k < nfields; k++) {
            sfpt_done->del_req(last--);
          }
          JVMState *jvms = sfpt_done->jvms();
          jvms->set_endoff(sfpt_done->req());
          // Now make a pass over the debug information replacing any references
          // to SafePointScalarObjectNode with the allocated object.
          int start = jvms->debug_start();
          int end   = jvms->debug_end();
          for (int i = start; i < end; i++) {
            if (sfpt_done->in(i)->is_SafePointScalarObject()) {
              SafePointScalarObjectNode* scobj = sfpt_done->in(i)->as_SafePointScalarObject();
              if (scobj->first_index() == sfpt_done->req() &&
                  scobj->n_fields() == (uint)nfields) {
                assert(scobj->alloc() == alloc, "sanity");
                sfpt_done->set_req(i, res);
              }
            }
          }
        }
#ifndef PRODUCT
        if (PrintEliminateAllocations) {
          if (field != NULL) {
            tty->print("=== At SafePoint node %d can't find value of Field: ",
                       sfpt->_idx);
            field->print();
            int field_idx = C->get_alias_index(field_addr_type);
            tty->print(" (alias_idx=%d)", field_idx);
          } else { // Array's element
            tty->print("=== At SafePoint node %d can't find value of array element [%d]",
                       sfpt->_idx, j);
          }
          tty->print(", which prevents elimination of: ");
          if (res == NULL)
            alloc->dump();
          else
            res->dump();
        }
#endif
        return false;
      }
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      if (UseCompressedOops && field_type->isa_narrowoop()) {
        // Enable "DecodeN(EncodeP(Allocate)) --> Allocate" transformation
        // to be able scalar replace the allocation.
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        if (field_val->is_EncodeP()) {
          field_val = field_val->in(1);
        } else {
          field_val = transform_later(new (C, 2) DecodeNNode(field_val, field_val->bottom_type()->make_ptr()));
        }
712
      }
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      sfpt->add_req(field_val);
    }
    JVMState *jvms = sfpt->jvms();
    jvms->set_endoff(sfpt->req());
    // Now make a pass over the debug information replacing any references
    // to the allocated object with "sobj"
    int start = jvms->debug_start();
    int end   = jvms->debug_end();
    for (int i = start; i < end; i++) {
      if (sfpt->in(i) == res) {
        sfpt->set_req(i, sobj);
      }
    }
    safepoints_done.append_if_missing(sfpt); // keep it for rollback
  }
  return true;
}

// Process users of eliminated allocation.
void PhaseMacroExpand::process_users_of_allocation(AllocateNode *alloc) {
  Node* res = alloc->result_cast();
  if (res != NULL) {
    for (DUIterator_Last jmin, j = res->last_outs(jmin); j >= jmin; ) {
      Node *use = res->last_out(j);
      uint oc1 = res->outcnt();

      if (use->is_AddP()) {
        for (DUIterator_Last kmin, k = use->last_outs(kmin); k >= kmin; ) {
          Node *n = use->last_out(k);
          uint oc2 = use->outcnt();
          if (n->is_Store()) {
            _igvn.replace_node(n, n->in(MemNode::Memory));
          } else {
            assert( n->Opcode() == Op_CastP2X, "CastP2X required");
            eliminate_card_mark(n);
          }
          k -= (oc2 - use->outcnt());
        }
      } else {
        assert( !use->is_SafePoint(), "safepoint uses must have been already elimiated");
        assert( use->Opcode() == Op_CastP2X, "CastP2X required");
        eliminate_card_mark(use);
      }
      j -= (oc1 - res->outcnt());
    }
    assert(res->outcnt() == 0, "all uses of allocated objects must be deleted");
    _igvn.remove_dead_node(res);
  }

  //
  // Process other users of allocation's projections
  //
  if (_resproj != NULL && _resproj->outcnt() != 0) {
    for (DUIterator_Last jmin, j = _resproj->last_outs(jmin); j >= jmin; ) {
      Node *use = _resproj->last_out(j);
      uint oc1 = _resproj->outcnt();
      if (use->is_Initialize()) {
        // Eliminate Initialize node.
        InitializeNode *init = use->as_Initialize();
        assert(init->outcnt() <= 2, "only a control and memory projection expected");
        Node *ctrl_proj = init->proj_out(TypeFunc::Control);
        if (ctrl_proj != NULL) {
           assert(init->in(TypeFunc::Control) == _fallthroughcatchproj, "allocation control projection");
          _igvn.replace_node(ctrl_proj, _fallthroughcatchproj);
        }
        Node *mem_proj = init->proj_out(TypeFunc::Memory);
        if (mem_proj != NULL) {
          Node *mem = init->in(TypeFunc::Memory);
#ifdef ASSERT
          if (mem->is_MergeMem()) {
            assert(mem->in(TypeFunc::Memory) == _memproj_fallthrough, "allocation memory projection");
          } else {
            assert(mem == _memproj_fallthrough, "allocation memory projection");
          }
#endif
          _igvn.replace_node(mem_proj, mem);
        }
      } else if (use->is_AddP()) {
        // raw memory addresses used only by the initialization
        _igvn.hash_delete(use);
        _igvn.subsume_node(use, C->top());
      } else  {
        assert(false, "only Initialize or AddP expected");
      }
      j -= (oc1 - _resproj->outcnt());
    }
  }
  if (_fallthroughcatchproj != NULL) {
    _igvn.replace_node(_fallthroughcatchproj, alloc->in(TypeFunc::Control));
  }
  if (_memproj_fallthrough != NULL) {
    _igvn.replace_node(_memproj_fallthrough, alloc->in(TypeFunc::Memory));
  }
  if (_memproj_catchall != NULL) {
    _igvn.replace_node(_memproj_catchall, C->top());
  }
  if (_ioproj_fallthrough != NULL) {
    _igvn.replace_node(_ioproj_fallthrough, alloc->in(TypeFunc::I_O));
  }
  if (_ioproj_catchall != NULL) {
    _igvn.replace_node(_ioproj_catchall, C->top());
  }
  if (_catchallcatchproj != NULL) {
    _igvn.replace_node(_catchallcatchproj, C->top());
  }
}

bool PhaseMacroExpand::eliminate_allocate_node(AllocateNode *alloc) {

  if (!EliminateAllocations || !alloc->_is_scalar_replaceable) {
    return false;
  }

  extract_call_projections(alloc);

  GrowableArray <SafePointNode *> safepoints;
  if (!can_eliminate_allocation(alloc, safepoints)) {
    return false;
  }

  if (!scalar_replacement(alloc, safepoints)) {
    return false;
  }

  process_users_of_allocation(alloc);

#ifndef PRODUCT
if (PrintEliminateAllocations) {
  if (alloc->is_AllocateArray())
    tty->print_cr("++++ Eliminated: %d AllocateArray", alloc->_idx);
  else
    tty->print_cr("++++ Eliminated: %d Allocate", alloc->_idx);
}
#endif

  return true;
}

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//---------------------------set_eden_pointers-------------------------
void PhaseMacroExpand::set_eden_pointers(Node* &eden_top_adr, Node* &eden_end_adr) {
  if (UseTLAB) {                // Private allocation: load from TLS
    Node* thread = transform_later(new (C, 1) ThreadLocalNode());
    int tlab_top_offset = in_bytes(JavaThread::tlab_top_offset());
    int tlab_end_offset = in_bytes(JavaThread::tlab_end_offset());
    eden_top_adr = basic_plus_adr(top()/*not oop*/, thread, tlab_top_offset);
    eden_end_adr = basic_plus_adr(top()/*not oop*/, thread, tlab_end_offset);
  } else {                      // Shared allocation: load from globals
    CollectedHeap* ch = Universe::heap();
    address top_adr = (address)ch->top_addr();
    address end_adr = (address)ch->end_addr();
    eden_top_adr = makecon(TypeRawPtr::make(top_adr));
    eden_end_adr = basic_plus_adr(eden_top_adr, end_adr - top_adr);
  }
}


Node* PhaseMacroExpand::make_load(Node* ctl, Node* mem, Node* base, int offset, const Type* value_type, BasicType bt) {
  Node* adr = basic_plus_adr(base, offset);
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  const TypePtr* adr_type = adr->bottom_type()->is_ptr();
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  Node* value = LoadNode::make(_igvn, ctl, mem, adr, adr_type, value_type, bt);
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  transform_later(value);
  return value;
}


Node* PhaseMacroExpand::make_store(Node* ctl, Node* mem, Node* base, int offset, Node* value, BasicType bt) {
  Node* adr = basic_plus_adr(base, offset);
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  mem = StoreNode::make(_igvn, ctl, mem, adr, NULL, value, bt);
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  transform_later(mem);
  return mem;
}

//=============================================================================
//
//                              A L L O C A T I O N
//
// Allocation attempts to be fast in the case of frequent small objects.
// It breaks down like this:
//
// 1) Size in doublewords is computed.  This is a constant for objects and
// variable for most arrays.  Doubleword units are used to avoid size
// overflow of huge doubleword arrays.  We need doublewords in the end for
// rounding.
//
// 2) Size is checked for being 'too large'.  Too-large allocations will go
// the slow path into the VM.  The slow path can throw any required
// exceptions, and does all the special checks for very large arrays.  The
// size test can constant-fold away for objects.  For objects with
// finalizers it constant-folds the otherway: you always go slow with
// finalizers.
//
// 3) If NOT using TLABs, this is the contended loop-back point.
// Load-Locked the heap top.  If using TLABs normal-load the heap top.
//
// 4) Check that heap top + size*8 < max.  If we fail go the slow ` route.
// NOTE: "top+size*8" cannot wrap the 4Gig line!  Here's why: for largish
// "size*8" we always enter the VM, where "largish" is a constant picked small
// enough that there's always space between the eden max and 4Gig (old space is
// there so it's quite large) and large enough that the cost of entering the VM
// is dwarfed by the cost to initialize the space.
//
// 5) If NOT using TLABs, Store-Conditional the adjusted heap top back
// down.  If contended, repeat at step 3.  If using TLABs normal-store
// adjusted heap top back down; there is no contention.
//
// 6) If !ZeroTLAB then Bulk-clear the object/array.  Fill in klass & mark
// fields.
//
// 7) Merge with the slow-path; cast the raw memory pointer to the correct
// oop flavor.
//
//=============================================================================
// FastAllocateSizeLimit value is in DOUBLEWORDS.
// Allocations bigger than this always go the slow route.
// This value must be small enough that allocation attempts that need to
// trigger exceptions go the slow route.  Also, it must be small enough so
// that heap_top + size_in_bytes does not wrap around the 4Gig limit.
//=============================================================================j//
// %%% Here is an old comment from parseHelper.cpp; is it outdated?
// The allocator will coalesce int->oop copies away.  See comment in
// coalesce.cpp about how this works.  It depends critically on the exact
// code shape produced here, so if you are changing this code shape
// make sure the GC info for the heap-top is correct in and around the
// slow-path call.
//

void PhaseMacroExpand::expand_allocate_common(
            AllocateNode* alloc, // allocation node to be expanded
            Node* length,  // array length for an array allocation
            const TypeFunc* slow_call_type, // Type of slow call
            address slow_call_address  // Address of slow call
    )
{

  Node* ctrl = alloc->in(TypeFunc::Control);
  Node* mem  = alloc->in(TypeFunc::Memory);
  Node* i_o  = alloc->in(TypeFunc::I_O);
  Node* size_in_bytes     = alloc->in(AllocateNode::AllocSize);
  Node* klass_node        = alloc->in(AllocateNode::KlassNode);
  Node* initial_slow_test = alloc->in(AllocateNode::InitialTest);

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  // With escape analysis, the entire memory state was needed to be able to
  // eliminate the allocation.  Since the allocations cannot be eliminated,
  // optimize it to the raw slice.
  if (mem->is_MergeMem()) {
    mem = mem->as_MergeMem()->memory_at(Compile::AliasIdxRaw);
  }

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  assert(ctrl != NULL, "must have control");
  // We need a Region and corresponding Phi's to merge the slow-path and fast-path results.
  // they will not be used if "always_slow" is set
  enum { slow_result_path = 1, fast_result_path = 2 };
  Node *result_region;
  Node *result_phi_rawmem;
  Node *result_phi_rawoop;
  Node *result_phi_i_o;

  // The initial slow comparison is a size check, the comparison
  // we want to do is a BoolTest::gt
  bool always_slow = false;
  int tv = _igvn.find_int_con(initial_slow_test, -1);
  if (tv >= 0) {
    always_slow = (tv == 1);
    initial_slow_test = NULL;
  } else {
    initial_slow_test = BoolNode::make_predicate(initial_slow_test, &_igvn);
  }

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  if (DTraceAllocProbes ||
      !UseTLAB && (!Universe::heap()->supports_inline_contig_alloc() ||
                   (UseConcMarkSweepGC && CMSIncrementalMode))) {
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    // Force slow-path allocation
    always_slow = true;
    initial_slow_test = NULL;
  }

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  enum { too_big_or_final_path = 1, need_gc_path = 2 };
  Node *slow_region = NULL;
  Node *toobig_false = ctrl;

  assert (initial_slow_test == NULL || !always_slow, "arguments must be consistent");
  // generate the initial test if necessary
  if (initial_slow_test != NULL ) {
    slow_region = new (C, 3) RegionNode(3);

    // Now make the initial failure test.  Usually a too-big test but
    // might be a TRUE for finalizers or a fancy class check for
    // newInstance0.
    IfNode *toobig_iff = new (C, 2) IfNode(ctrl, initial_slow_test, PROB_MIN, COUNT_UNKNOWN);
    transform_later(toobig_iff);
    // Plug the failing-too-big test into the slow-path region
    Node *toobig_true = new (C, 1) IfTrueNode( toobig_iff );
    transform_later(toobig_true);
    slow_region    ->init_req( too_big_or_final_path, toobig_true );
    toobig_false = new (C, 1) IfFalseNode( toobig_iff );
    transform_later(toobig_false);
  } else {         // No initial test, just fall into next case
    toobig_false = ctrl;
    debug_only(slow_region = NodeSentinel);
  }

  Node *slow_mem = mem;  // save the current memory state for slow path
  // generate the fast allocation code unless we know that the initial test will always go slow
  if (!always_slow) {
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    Node* eden_top_adr;
    Node* eden_end_adr;

    set_eden_pointers(eden_top_adr, eden_end_adr);

    // Load Eden::end.  Loop invariant and hoisted.
    //
    // Note: We set the control input on "eden_end" and "old_eden_top" when using
    //       a TLAB to work around a bug where these values were being moved across
    //       a safepoint.  These are not oops, so they cannot be include in the oop
    //       map, but the can be changed by a GC.   The proper way to fix this would
    //       be to set the raw memory state when generating a  SafepointNode.  However
    //       this will require extensive changes to the loop optimization in order to
    //       prevent a degradation of the optimization.
    //       See comment in memnode.hpp, around line 227 in class LoadPNode.
    Node *eden_end = make_load(ctrl, mem, eden_end_adr, 0, TypeRawPtr::BOTTOM, T_ADDRESS);

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    // allocate the Region and Phi nodes for the result
    result_region = new (C, 3) RegionNode(3);
    result_phi_rawmem = new (C, 3) PhiNode( result_region, Type::MEMORY, TypeRawPtr::BOTTOM );
    result_phi_rawoop = new (C, 3) PhiNode( result_region, TypeRawPtr::BOTTOM );
    result_phi_i_o    = new (C, 3) PhiNode( result_region, Type::ABIO ); // I/O is used for Prefetch

    // We need a Region for the loop-back contended case.
    enum { fall_in_path = 1, contended_loopback_path = 2 };
    Node *contended_region;
    Node *contended_phi_rawmem;
    if( UseTLAB ) {
      contended_region = toobig_false;
      contended_phi_rawmem = mem;
    } else {
      contended_region = new (C, 3) RegionNode(3);
      contended_phi_rawmem = new (C, 3) PhiNode( contended_region, Type::MEMORY, TypeRawPtr::BOTTOM);
      // Now handle the passing-too-big test.  We fall into the contended
      // loop-back merge point.
      contended_region    ->init_req( fall_in_path, toobig_false );
      contended_phi_rawmem->init_req( fall_in_path, mem );
      transform_later(contended_region);
      transform_later(contended_phi_rawmem);
    }

    // Load(-locked) the heap top.
    // See note above concerning the control input when using a TLAB
    Node *old_eden_top = UseTLAB
      ? new (C, 3) LoadPNode     ( ctrl, contended_phi_rawmem, eden_top_adr, TypeRawPtr::BOTTOM, TypeRawPtr::BOTTOM )
      : new (C, 3) LoadPLockedNode( contended_region, contended_phi_rawmem, eden_top_adr );

    transform_later(old_eden_top);
    // Add to heap top to get a new heap top
    Node *new_eden_top = new (C, 4) AddPNode( top(), old_eden_top, size_in_bytes );
    transform_later(new_eden_top);
    // Check for needing a GC; compare against heap end
    Node *needgc_cmp = new (C, 3) CmpPNode( new_eden_top, eden_end );
    transform_later(needgc_cmp);
    Node *needgc_bol = new (C, 2) BoolNode( needgc_cmp, BoolTest::ge );
    transform_later(needgc_bol);
    IfNode *needgc_iff = new (C, 2) IfNode(contended_region, needgc_bol, PROB_UNLIKELY_MAG(4), COUNT_UNKNOWN );
    transform_later(needgc_iff);

    // Plug the failing-heap-space-need-gc test into the slow-path region
    Node *needgc_true = new (C, 1) IfTrueNode( needgc_iff );
    transform_later(needgc_true);
    if( initial_slow_test ) {
      slow_region    ->init_req( need_gc_path, needgc_true );
      // This completes all paths into the slow merge point
      transform_later(slow_region);
    } else {                      // No initial slow path needed!
      // Just fall from the need-GC path straight into the VM call.
      slow_region    = needgc_true;
    }
    // No need for a GC.  Setup for the Store-Conditional
    Node *needgc_false = new (C, 1) IfFalseNode( needgc_iff );
    transform_later(needgc_false);

    // Grab regular I/O before optional prefetch may change it.
    // Slow-path does no I/O so just set it to the original I/O.
    result_phi_i_o->init_req( slow_result_path, i_o );

    i_o = prefetch_allocation(i_o, needgc_false, contended_phi_rawmem,
                              old_eden_top, new_eden_top, length);

    // Store (-conditional) the modified eden top back down.
    // StorePConditional produces flags for a test PLUS a modified raw
    // memory state.
    Node *store_eden_top;
    Node *fast_oop_ctrl;
    if( UseTLAB ) {
      store_eden_top = new (C, 4) StorePNode( needgc_false, contended_phi_rawmem, eden_top_adr, TypeRawPtr::BOTTOM, new_eden_top );
      transform_later(store_eden_top);
      fast_oop_ctrl = needgc_false; // No contention, so this is the fast path
    } else {
      store_eden_top = new (C, 5) StorePConditionalNode( needgc_false, contended_phi_rawmem, eden_top_adr, new_eden_top, old_eden_top );
      transform_later(store_eden_top);
      Node *contention_check = new (C, 2) BoolNode( store_eden_top, BoolTest::ne );
      transform_later(contention_check);
      store_eden_top = new (C, 1) SCMemProjNode(store_eden_top);
      transform_later(store_eden_top);

      // If not using TLABs, check to see if there was contention.
      IfNode *contention_iff = new (C, 2) IfNode ( needgc_false, contention_check, PROB_MIN, COUNT_UNKNOWN );
      transform_later(contention_iff);
      Node *contention_true = new (C, 1) IfTrueNode( contention_iff );
      transform_later(contention_true);
      // If contention, loopback and try again.
      contended_region->init_req( contended_loopback_path, contention_true );
      contended_phi_rawmem->init_req( contended_loopback_path, store_eden_top );

      // Fast-path succeeded with no contention!
      Node *contention_false = new (C, 1) IfFalseNode( contention_iff );
      transform_later(contention_false);
      fast_oop_ctrl = contention_false;
    }

    // Rename successful fast-path variables to make meaning more obvious
    Node* fast_oop        = old_eden_top;
    Node* fast_oop_rawmem = store_eden_top;
    fast_oop_rawmem = initialize_object(alloc,
                                        fast_oop_ctrl, fast_oop_rawmem, fast_oop,
                                        klass_node, length, size_in_bytes);

    if (ExtendedDTraceProbes) {
      // Slow-path call
      int size = TypeFunc::Parms + 2;
      CallLeafNode *call = new (C, size) CallLeafNode(OptoRuntime::dtrace_object_alloc_Type(),
                                                      CAST_FROM_FN_PTR(address, SharedRuntime::dtrace_object_alloc_base),
                                                      "dtrace_object_alloc",
                                                      TypeRawPtr::BOTTOM);

      // Get base of thread-local storage area
      Node* thread = new (C, 1) ThreadLocalNode();
      transform_later(thread);

      call->init_req(TypeFunc::Parms+0, thread);
      call->init_req(TypeFunc::Parms+1, fast_oop);
      call->init_req( TypeFunc::Control, fast_oop_ctrl );
      call->init_req( TypeFunc::I_O    , top() )        ;   // does no i/o
      call->init_req( TypeFunc::Memory , fast_oop_rawmem );
      call->init_req( TypeFunc::ReturnAdr, alloc->in(TypeFunc::ReturnAdr) );
      call->init_req( TypeFunc::FramePtr, alloc->in(TypeFunc::FramePtr) );
      transform_later(call);
      fast_oop_ctrl = new (C, 1) ProjNode(call,TypeFunc::Control);
      transform_later(fast_oop_ctrl);
      fast_oop_rawmem = new (C, 1) ProjNode(call,TypeFunc::Memory);
      transform_later(fast_oop_rawmem);
    }

    // Plug in the successful fast-path into the result merge point
    result_region    ->init_req( fast_result_path, fast_oop_ctrl );
    result_phi_rawoop->init_req( fast_result_path, fast_oop );
    result_phi_i_o   ->init_req( fast_result_path, i_o );
    result_phi_rawmem->init_req( fast_result_path, fast_oop_rawmem );
  } else {
    slow_region = ctrl;
  }

  // Generate slow-path call
  CallNode *call = new (C, slow_call_type->domain()->cnt())
    CallStaticJavaNode(slow_call_type, slow_call_address,
                       OptoRuntime::stub_name(slow_call_address),
                       alloc->jvms()->bci(),
                       TypePtr::BOTTOM);
  call->init_req( TypeFunc::Control, slow_region );
  call->init_req( TypeFunc::I_O    , top() )     ;   // does no i/o
  call->init_req( TypeFunc::Memory , slow_mem ); // may gc ptrs
  call->init_req( TypeFunc::ReturnAdr, alloc->in(TypeFunc::ReturnAdr) );
  call->init_req( TypeFunc::FramePtr, alloc->in(TypeFunc::FramePtr) );

  call->init_req(TypeFunc::Parms+0, klass_node);
  if (length != NULL) {
    call->init_req(TypeFunc::Parms+1, length);
  }

  // Copy debug information and adjust JVMState information, then replace
  // allocate node with the call
  copy_call_debug_info((CallNode *) alloc,  call);
  if (!always_slow) {
    call->set_cnt(PROB_UNLIKELY_MAG(4));  // Same effect as RC_UNCOMMON.
  }
  _igvn.hash_delete(alloc);
  _igvn.subsume_node(alloc, call);
  transform_later(call);

  // Identify the output projections from the allocate node and
  // adjust any references to them.
  // The control and io projections look like:
  //
  //        v---Proj(ctrl) <-----+   v---CatchProj(ctrl)
  //  Allocate                   Catch
  //        ^---Proj(io) <-------+   ^---CatchProj(io)
  //
  //  We are interested in the CatchProj nodes.
  //
  extract_call_projections(call);

  // An allocate node has separate memory projections for the uses on the control and i_o paths
  // Replace uses of the control memory projection with result_phi_rawmem (unless we are only generating a slow call)
  if (!always_slow && _memproj_fallthrough != NULL) {
    for (DUIterator_Fast imax, i = _memproj_fallthrough->fast_outs(imax); i < imax; i++) {
      Node *use = _memproj_fallthrough->fast_out(i);
      _igvn.hash_delete(use);
      imax -= replace_input(use, _memproj_fallthrough, result_phi_rawmem);
      _igvn._worklist.push(use);
      // back up iterator
      --i;
    }
  }
  // Now change uses of _memproj_catchall to use _memproj_fallthrough and delete _memproj_catchall so
  // we end up with a call that has only 1 memory projection
  if (_memproj_catchall != NULL ) {
    if (_memproj_fallthrough == NULL) {
      _memproj_fallthrough = new (C, 1) ProjNode(call, TypeFunc::Memory);
      transform_later(_memproj_fallthrough);
    }
    for (DUIterator_Fast imax, i = _memproj_catchall->fast_outs(imax); i < imax; i++) {
      Node *use = _memproj_catchall->fast_out(i);
      _igvn.hash_delete(use);
      imax -= replace_input(use, _memproj_catchall, _memproj_fallthrough);
      _igvn._worklist.push(use);
      // back up iterator
      --i;
    }
  }

  mem = result_phi_rawmem;

  // An allocate node has separate i_o projections for the uses on the control and i_o paths
  // Replace uses of the control i_o projection with result_phi_i_o (unless we are only generating a slow call)
  if (_ioproj_fallthrough == NULL) {
    _ioproj_fallthrough = new (C, 1) ProjNode(call, TypeFunc::I_O);
    transform_later(_ioproj_fallthrough);
  } else if (!always_slow) {
    for (DUIterator_Fast imax, i = _ioproj_fallthrough->fast_outs(imax); i < imax; i++) {
      Node *use = _ioproj_fallthrough->fast_out(i);

      _igvn.hash_delete(use);
      imax -= replace_input(use, _ioproj_fallthrough, result_phi_i_o);
      _igvn._worklist.push(use);
      // back up iterator
      --i;
    }
  }
  // Now change uses of _ioproj_catchall to use _ioproj_fallthrough and delete _ioproj_catchall so
  // we end up with a call that has only 1 control projection
  if (_ioproj_catchall != NULL ) {
    for (DUIterator_Fast imax, i = _ioproj_catchall->fast_outs(imax); i < imax; i++) {
      Node *use = _ioproj_catchall->fast_out(i);
      _igvn.hash_delete(use);
      imax -= replace_input(use, _ioproj_catchall, _ioproj_fallthrough);
      _igvn._worklist.push(use);
      // back up iterator
      --i;
    }
  }

  // if we generated only a slow call, we are done
  if (always_slow)
    return;


  if (_fallthroughcatchproj != NULL) {
    ctrl = _fallthroughcatchproj->clone();
    transform_later(ctrl);
    _igvn.hash_delete(_fallthroughcatchproj);
    _igvn.subsume_node(_fallthroughcatchproj, result_region);
  } else {
    ctrl = top();
  }
  Node *slow_result;
  if (_resproj == NULL) {
    // no uses of the allocation result
    slow_result = top();
  } else {
    slow_result = _resproj->clone();
    transform_later(slow_result);
    _igvn.hash_delete(_resproj);
    _igvn.subsume_node(_resproj, result_phi_rawoop);
  }

  // Plug slow-path into result merge point
  result_region    ->init_req( slow_result_path, ctrl );
  result_phi_rawoop->init_req( slow_result_path, slow_result);
  result_phi_rawmem->init_req( slow_result_path, _memproj_fallthrough );
  transform_later(result_region);
  transform_later(result_phi_rawoop);
  transform_later(result_phi_rawmem);
  transform_later(result_phi_i_o);
  // This completes all paths into the result merge point
}


// Helper for PhaseMacroExpand::expand_allocate_common.
// Initializes the newly-allocated storage.
Node*
PhaseMacroExpand::initialize_object(AllocateNode* alloc,
                                    Node* control, Node* rawmem, Node* object,
                                    Node* klass_node, Node* length,
                                    Node* size_in_bytes) {
  InitializeNode* init = alloc->initialization();
  // Store the klass & mark bits
  Node* mark_node = NULL;
  // For now only enable fast locking for non-array types
  if (UseBiasedLocking && (length == NULL)) {
    mark_node = make_load(NULL, rawmem, klass_node, Klass::prototype_header_offset_in_bytes() + sizeof(oopDesc), TypeRawPtr::BOTTOM, T_ADDRESS);
  } else {
    mark_node = makecon(TypeRawPtr::make((address)markOopDesc::prototype()));
  }
  rawmem = make_store(control, rawmem, object, oopDesc::mark_offset_in_bytes(), mark_node, T_ADDRESS);
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  rawmem = make_store(control, rawmem, object, oopDesc::klass_offset_in_bytes(), klass_node, T_OBJECT);
  int header_size = alloc->minimum_header_size();  // conservatively small

  // Array length
  if (length != NULL) {         // Arrays need length field
    rawmem = make_store(control, rawmem, object, arrayOopDesc::length_offset_in_bytes(), length, T_INT);
    // conservatively small header size:
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    header_size = arrayOopDesc::base_offset_in_bytes(T_BYTE);
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    ciKlass* k = _igvn.type(klass_node)->is_klassptr()->klass();
    if (k->is_array_klass())    // we know the exact header size in most cases:
      header_size = Klass::layout_helper_header_size(k->layout_helper());
  }

  // Clear the object body, if necessary.
  if (init == NULL) {
    // The init has somehow disappeared; be cautious and clear everything.
    //
    // This can happen if a node is allocated but an uncommon trap occurs
    // immediately.  In this case, the Initialize gets associated with the
    // trap, and may be placed in a different (outer) loop, if the Allocate
    // is in a loop.  If (this is rare) the inner loop gets unrolled, then
    // there can be two Allocates to one Initialize.  The answer in all these
    // edge cases is safety first.  It is always safe to clear immediately
    // within an Allocate, and then (maybe or maybe not) clear some more later.
    if (!ZeroTLAB)
      rawmem = ClearArrayNode::clear_memory(control, rawmem, object,
                                            header_size, size_in_bytes,
                                            &_igvn);
  } else {
    if (!init->is_complete()) {
      // Try to win by zeroing only what the init does not store.
      // We can also try to do some peephole optimizations,
      // such as combining some adjacent subword stores.
      rawmem = init->complete_stores(control, rawmem, object,
                                     header_size, size_in_bytes, &_igvn);
    }
    // We have no more use for this link, since the AllocateNode goes away:
    init->set_req(InitializeNode::RawAddress, top());
    // (If we keep the link, it just confuses the register allocator,
    // who thinks he sees a real use of the address by the membar.)
  }

  return rawmem;
}

// Generate prefetch instructions for next allocations.
Node* PhaseMacroExpand::prefetch_allocation(Node* i_o, Node*& needgc_false,
                                        Node*& contended_phi_rawmem,
                                        Node* old_eden_top, Node* new_eden_top,
                                        Node* length) {
   if( UseTLAB && AllocatePrefetchStyle == 2 ) {
      // Generate prefetch allocation with watermark check.
      // As an allocation hits the watermark, we will prefetch starting
      // at a "distance" away from watermark.
      enum { fall_in_path = 1, pf_path = 2 };

      Node *pf_region = new (C, 3) RegionNode(3);
      Node *pf_phi_rawmem = new (C, 3) PhiNode( pf_region, Type::MEMORY,
                                                TypeRawPtr::BOTTOM );
      // I/O is used for Prefetch
      Node *pf_phi_abio = new (C, 3) PhiNode( pf_region, Type::ABIO );

      Node *thread = new (C, 1) ThreadLocalNode();
      transform_later(thread);

      Node *eden_pf_adr = new (C, 4) AddPNode( top()/*not oop*/, thread,
                   _igvn.MakeConX(in_bytes(JavaThread::tlab_pf_top_offset())) );
      transform_later(eden_pf_adr);

      Node *old_pf_wm = new (C, 3) LoadPNode( needgc_false,
                                   contended_phi_rawmem, eden_pf_adr,
                                   TypeRawPtr::BOTTOM, TypeRawPtr::BOTTOM );
      transform_later(old_pf_wm);

      // check against new_eden_top
      Node *need_pf_cmp = new (C, 3) CmpPNode( new_eden_top, old_pf_wm );
      transform_later(need_pf_cmp);
      Node *need_pf_bol = new (C, 2) BoolNode( need_pf_cmp, BoolTest::ge );
      transform_later(need_pf_bol);
      IfNode *need_pf_iff = new (C, 2) IfNode( needgc_false, need_pf_bol,
                                       PROB_UNLIKELY_MAG(4), COUNT_UNKNOWN );
      transform_later(need_pf_iff);

      // true node, add prefetchdistance
      Node *need_pf_true = new (C, 1) IfTrueNode( need_pf_iff );
      transform_later(need_pf_true);

      Node *need_pf_false = new (C, 1) IfFalseNode( need_pf_iff );
      transform_later(need_pf_false);

      Node *new_pf_wmt = new (C, 4) AddPNode( top(), old_pf_wm,
                                    _igvn.MakeConX(AllocatePrefetchDistance) );
      transform_later(new_pf_wmt );
      new_pf_wmt->set_req(0, need_pf_true);

      Node *store_new_wmt = new (C, 4) StorePNode( need_pf_true,
                                       contended_phi_rawmem, eden_pf_adr,
                                       TypeRawPtr::BOTTOM, new_pf_wmt );
      transform_later(store_new_wmt);

      // adding prefetches
      pf_phi_abio->init_req( fall_in_path, i_o );

      Node *prefetch_adr;
      Node *prefetch;
      uint lines = AllocatePrefetchDistance / AllocatePrefetchStepSize;
      uint step_size = AllocatePrefetchStepSize;
      uint distance = 0;

      for ( uint i = 0; i < lines; i++ ) {
        prefetch_adr = new (C, 4) AddPNode( old_pf_wm, new_pf_wmt,
                                            _igvn.MakeConX(distance) );
        transform_later(prefetch_adr);
        prefetch = new (C, 3) PrefetchWriteNode( i_o, prefetch_adr );
        transform_later(prefetch);
        distance += step_size;
        i_o = prefetch;
      }
      pf_phi_abio->set_req( pf_path, i_o );

      pf_region->init_req( fall_in_path, need_pf_false );
      pf_region->init_req( pf_path, need_pf_true );

      pf_phi_rawmem->init_req( fall_in_path, contended_phi_rawmem );
      pf_phi_rawmem->init_req( pf_path, store_new_wmt );

      transform_later(pf_region);
      transform_later(pf_phi_rawmem);
      transform_later(pf_phi_abio);

      needgc_false = pf_region;
      contended_phi_rawmem = pf_phi_rawmem;
      i_o = pf_phi_abio;
   } else if( AllocatePrefetchStyle > 0 ) {
      // Insert a prefetch for each allocation only on the fast-path
      Node *prefetch_adr;
      Node *prefetch;
      // Generate several prefetch instructions only for arrays.
      uint lines = (length != NULL) ? AllocatePrefetchLines : 1;
      uint step_size = AllocatePrefetchStepSize;
      uint distance = AllocatePrefetchDistance;
      for ( uint i = 0; i < lines; i++ ) {
        prefetch_adr = new (C, 4) AddPNode( old_eden_top, new_eden_top,
                                            _igvn.MakeConX(distance) );
        transform_later(prefetch_adr);
        prefetch = new (C, 3) PrefetchWriteNode( i_o, prefetch_adr );
        // Do not let it float too high, since if eden_top == eden_end,
        // both might be null.
        if( i == 0 ) { // Set control for first prefetch, next follows it
          prefetch->init_req(0, needgc_false);
        }
        transform_later(prefetch);
        distance += step_size;
        i_o = prefetch;
      }
   }
   return i_o;
}


void PhaseMacroExpand::expand_allocate(AllocateNode *alloc) {
  expand_allocate_common(alloc, NULL,
                         OptoRuntime::new_instance_Type(),
                         OptoRuntime::new_instance_Java());
}

void PhaseMacroExpand::expand_allocate_array(AllocateArrayNode *alloc) {
  Node* length = alloc->in(AllocateNode::ALength);
  expand_allocate_common(alloc, length,
                         OptoRuntime::new_array_Type(),
                         OptoRuntime::new_array_Java());
}


// we have determined that this lock/unlock can be eliminated, we simply
// eliminate the node without expanding it.
//
// Note:  The membar's associated with the lock/unlock are currently not
//        eliminated.  This should be investigated as a future enhancement.
//
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bool PhaseMacroExpand::eliminate_locking_node(AbstractLockNode *alock) {

  if (!alock->is_eliminated()) {
    return false;
  }
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  if (alock->is_Lock() && !alock->is_coarsened()) {
      // Create new "eliminated" BoxLock node and use it
      // in monitor debug info for the same object.
      BoxLockNode* oldbox = alock->box_node()->as_BoxLock();
      Node* obj = alock->obj_node();
      if (!oldbox->is_eliminated()) {
        BoxLockNode* newbox = oldbox->clone()->as_BoxLock();
        newbox->set_eliminated();
        transform_later(newbox);
        // Replace old box node with new box for all users
        // of the same object.
        for (uint i = 0; i < oldbox->outcnt();) {

          bool next_edge = true;
          Node* u = oldbox->raw_out(i);
          if (u == alock) {
            i++;
            continue; // It will be removed below
          }
          if (u->is_Lock() &&
              u->as_Lock()->obj_node() == obj &&
              // oldbox could be referenced in debug info also
              u->as_Lock()->box_node() == oldbox) {
            assert(u->as_Lock()->is_eliminated(), "sanity");
            _igvn.hash_delete(u);
            u->set_req(TypeFunc::Parms + 1, newbox);
            next_edge = false;
#ifdef ASSERT
          } else if (u->is_Unlock() && u->as_Unlock()->obj_node() == obj) {
            assert(u->as_Unlock()->is_eliminated(), "sanity");
#endif
          }
          // Replace old box in monitor debug info.
          if (u->is_SafePoint() && u->as_SafePoint()->jvms()) {
            SafePointNode* sfn = u->as_SafePoint();
            JVMState* youngest_jvms = sfn->jvms();
            int max_depth = youngest_jvms->depth();
            for (int depth = 1; depth <= max_depth; depth++) {
              JVMState* jvms = youngest_jvms->of_depth(depth);
              int num_mon  = jvms->nof_monitors();
              // Loop over monitors
              for (int idx = 0; idx < num_mon; idx++) {
                Node* obj_node = sfn->monitor_obj(jvms, idx);
                Node* box_node = sfn->monitor_box(jvms, idx);
                if (box_node == oldbox && obj_node == obj) {
                  int j = jvms->monitor_box_offset(idx);
                  _igvn.hash_delete(u);
                  u->set_req(j, newbox);
                  next_edge = false;
                }
              } // for (int idx = 0;
            } // for (int depth = 1;
          } // if (u->is_SafePoint()
          if (next_edge) i++;
        } // for (uint i = 0; i < oldbox->outcnt();)
      } // if (!oldbox->is_eliminated())
  } // if (alock->is_Lock() && !lock->is_coarsened())
1569 1570 1571 1572 1573 1574 1575 1576 1577 1578 1579 1580 1581 1582 1583 1584 1585 1586 1587 1588 1589 1590 1591 1592

  #ifndef PRODUCT
  if (PrintEliminateLocks) {
    if (alock->is_Lock()) {
      tty->print_cr("++++ Eliminating: %d Lock", alock->_idx);
    } else {
      tty->print_cr("++++ Eliminating: %d Unlock", alock->_idx);
    }
  }
  #endif

  Node* mem  = alock->in(TypeFunc::Memory);
  Node* ctrl = alock->in(TypeFunc::Control);

  extract_call_projections(alock);
  // There are 2 projections from the lock.  The lock node will
  // be deleted when its last use is subsumed below.
  assert(alock->outcnt() == 2 &&
         _fallthroughproj != NULL &&
         _memproj_fallthrough != NULL,
         "Unexpected projections from Lock/Unlock");

  Node* fallthroughproj = _fallthroughproj;
  Node* memproj_fallthrough = _memproj_fallthrough;
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  // The memory projection from a lock/unlock is RawMem
  // The input to a Lock is merged memory, so extract its RawMem input
  // (unless the MergeMem has been optimized away.)
  if (alock->is_Lock()) {
1598 1599 1600 1601 1602 1603 1604 1605 1606
    // Seach for MemBarAcquire node and delete it also.
    MemBarNode* membar = fallthroughproj->unique_ctrl_out()->as_MemBar();
    assert(membar != NULL && membar->Opcode() == Op_MemBarAcquire, "");
    Node* ctrlproj = membar->proj_out(TypeFunc::Control);
    Node* memproj = membar->proj_out(TypeFunc::Memory);
    _igvn.hash_delete(ctrlproj);
    _igvn.subsume_node(ctrlproj, fallthroughproj);
    _igvn.hash_delete(memproj);
    _igvn.subsume_node(memproj, memproj_fallthrough);
1607 1608 1609 1610 1611 1612 1613 1614 1615

    // Delete FastLock node also if this Lock node is unique user
    // (a loop peeling may clone a Lock node).
    Node* flock = alock->as_Lock()->fastlock_node();
    if (flock->outcnt() == 1) {
      assert(flock->unique_out() == alock, "sanity");
      _igvn.hash_delete(flock);
      _igvn.subsume_node(flock, top());
    }
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  }

1618 1619 1620 1621 1622 1623 1624 1625 1626 1627 1628 1629 1630 1631 1632 1633 1634 1635 1636 1637 1638
  // Seach for MemBarRelease node and delete it also.
  if (alock->is_Unlock() && ctrl != NULL && ctrl->is_Proj() &&
      ctrl->in(0)->is_MemBar()) {
    MemBarNode* membar = ctrl->in(0)->as_MemBar();
    assert(membar->Opcode() == Op_MemBarRelease &&
           mem->is_Proj() && membar == mem->in(0), "");
    _igvn.hash_delete(fallthroughproj);
    _igvn.subsume_node(fallthroughproj, ctrl);
    _igvn.hash_delete(memproj_fallthrough);
    _igvn.subsume_node(memproj_fallthrough, mem);
    fallthroughproj = ctrl;
    memproj_fallthrough = mem;
    ctrl = membar->in(TypeFunc::Control);
    mem  = membar->in(TypeFunc::Memory);
  }

  _igvn.hash_delete(fallthroughproj);
  _igvn.subsume_node(fallthroughproj, ctrl);
  _igvn.hash_delete(memproj_fallthrough);
  _igvn.subsume_node(memproj_fallthrough, mem);
  return true;
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}


//------------------------------expand_lock_node----------------------
void PhaseMacroExpand::expand_lock_node(LockNode *lock) {

  Node* ctrl = lock->in(TypeFunc::Control);
  Node* mem = lock->in(TypeFunc::Memory);
  Node* obj = lock->obj_node();
  Node* box = lock->box_node();
1649
  Node* flock = lock->fastlock_node();
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  // Make the merge point
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  Node *region;
  Node *mem_phi;
  Node *slow_path;

  if (UseOptoBiasInlining) {
    /*
     *  See the full descrition in MacroAssembler::biased_locking_enter().
     *
     *  if( (mark_word & biased_lock_mask) == biased_lock_pattern ) {
     *    // The object is biased.
     *    proto_node = klass->prototype_header;
     *    o_node = thread | proto_node;
     *    x_node = o_node ^ mark_word;
     *    if( (x_node & ~age_mask) == 0 ) { // Biased to the current thread ?
     *      // Done.
     *    } else {
     *      if( (x_node & biased_lock_mask) != 0 ) {
     *        // The klass's prototype header is no longer biased.
     *        cas(&mark_word, mark_word, proto_node)
     *        goto cas_lock;
     *      } else {
     *        // The klass's prototype header is still biased.
     *        if( (x_node & epoch_mask) != 0 ) { // Expired epoch?
     *          old = mark_word;
     *          new = o_node;
     *        } else {
     *          // Different thread or anonymous biased.
     *          old = mark_word & (epoch_mask | age_mask | biased_lock_mask);
     *          new = thread | old;
     *        }
     *        // Try to rebias.
     *        if( cas(&mark_word, old, new) == 0 ) {
     *          // Done.
     *        } else {
     *          goto slow_path; // Failed.
     *        }
     *      }
     *    }
     *  } else {
     *    // The object is not biased.
     *    cas_lock:
     *    if( FastLock(obj) == 0 ) {
     *      // Done.
     *    } else {
     *      slow_path:
     *      OptoRuntime::complete_monitor_locking_Java(obj);
     *    }
     *  }
     */

    region  = new (C, 5) RegionNode(5);
    // create a Phi for the memory state
    mem_phi = new (C, 5) PhiNode( region, Type::MEMORY, TypeRawPtr::BOTTOM);

    Node* fast_lock_region  = new (C, 3) RegionNode(3);
    Node* fast_lock_mem_phi = new (C, 3) PhiNode( fast_lock_region, Type::MEMORY, TypeRawPtr::BOTTOM);

    // First, check mark word for the biased lock pattern.
    Node* mark_node = make_load(ctrl, mem, obj, oopDesc::mark_offset_in_bytes(), TypeX_X, TypeX_X->basic_type());

    // Get fast path - mark word has the biased lock pattern.
    ctrl = opt_bits_test(ctrl, fast_lock_region, 1, mark_node,
                         markOopDesc::biased_lock_mask_in_place,
                         markOopDesc::biased_lock_pattern, true);
    // fast_lock_region->in(1) is set to slow path.
    fast_lock_mem_phi->init_req(1, mem);

    // Now check that the lock is biased to the current thread and has
    // the same epoch and bias as Klass::_prototype_header.

    // Special-case a fresh allocation to avoid building nodes:
    Node* klass_node = AllocateNode::Ideal_klass(obj, &_igvn);
    if (klass_node == NULL) {
      Node* k_adr = basic_plus_adr(obj, oopDesc::klass_offset_in_bytes());
      klass_node = transform_later( LoadKlassNode::make(_igvn, mem, k_adr, _igvn.type(k_adr)->is_ptr()) );
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#ifdef _LP64
      if (UseCompressedOops && klass_node->is_DecodeN()) {
        assert(klass_node->in(1)->Opcode() == Op_LoadNKlass, "sanity");
        klass_node->in(1)->init_req(0, ctrl);
      } else
#endif
      klass_node->init_req(0, ctrl);
1734 1735
    }
    Node *proto_node = make_load(ctrl, mem, klass_node, Klass::prototype_header_offset_in_bytes() + sizeof(oopDesc), TypeX_X, TypeX_X->basic_type());
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1737 1738 1739 1740 1741 1742 1743 1744 1745 1746 1747 1748 1749 1750 1751 1752 1753 1754 1755 1756 1757 1758 1759 1760 1761 1762 1763 1764 1765 1766 1767 1768 1769 1770 1771 1772 1773 1774 1775 1776 1777 1778 1779 1780 1781 1782 1783 1784 1785 1786 1787 1788 1789 1790 1791 1792 1793 1794 1795 1796 1797 1798 1799 1800 1801 1802 1803 1804 1805 1806 1807 1808 1809 1810 1811 1812 1813 1814 1815 1816 1817 1818 1819 1820 1821 1822 1823 1824 1825 1826 1827 1828 1829 1830 1831 1832 1833 1834 1835 1836 1837 1838 1839 1840 1841 1842 1843 1844 1845
    Node* thread = transform_later(new (C, 1) ThreadLocalNode());
    Node* cast_thread = transform_later(new (C, 2) CastP2XNode(ctrl, thread));
    Node* o_node = transform_later(new (C, 3) OrXNode(cast_thread, proto_node));
    Node* x_node = transform_later(new (C, 3) XorXNode(o_node, mark_node));

    // Get slow path - mark word does NOT match the value.
    Node* not_biased_ctrl =  opt_bits_test(ctrl, region, 3, x_node,
                                      (~markOopDesc::age_mask_in_place), 0);
    // region->in(3) is set to fast path - the object is biased to the current thread.
    mem_phi->init_req(3, mem);


    // Mark word does NOT match the value (thread | Klass::_prototype_header).


    // First, check biased pattern.
    // Get fast path - _prototype_header has the same biased lock pattern.
    ctrl =  opt_bits_test(not_biased_ctrl, fast_lock_region, 2, x_node,
                          markOopDesc::biased_lock_mask_in_place, 0, true);

    not_biased_ctrl = fast_lock_region->in(2); // Slow path
    // fast_lock_region->in(2) - the prototype header is no longer biased
    // and we have to revoke the bias on this object.
    // We are going to try to reset the mark of this object to the prototype
    // value and fall through to the CAS-based locking scheme.
    Node* adr = basic_plus_adr(obj, oopDesc::mark_offset_in_bytes());
    Node* cas = new (C, 5) StoreXConditionalNode(not_biased_ctrl, mem, adr,
                                                 proto_node, mark_node);
    transform_later(cas);
    Node* proj = transform_later( new (C, 1) SCMemProjNode(cas));
    fast_lock_mem_phi->init_req(2, proj);


    // Second, check epoch bits.
    Node* rebiased_region  = new (C, 3) RegionNode(3);
    Node* old_phi = new (C, 3) PhiNode( rebiased_region, TypeX_X);
    Node* new_phi = new (C, 3) PhiNode( rebiased_region, TypeX_X);

    // Get slow path - mark word does NOT match epoch bits.
    Node* epoch_ctrl =  opt_bits_test(ctrl, rebiased_region, 1, x_node,
                                      markOopDesc::epoch_mask_in_place, 0);
    // The epoch of the current bias is not valid, attempt to rebias the object
    // toward the current thread.
    rebiased_region->init_req(2, epoch_ctrl);
    old_phi->init_req(2, mark_node);
    new_phi->init_req(2, o_node);

    // rebiased_region->in(1) is set to fast path.
    // The epoch of the current bias is still valid but we know
    // nothing about the owner; it might be set or it might be clear.
    Node* cmask   = MakeConX(markOopDesc::biased_lock_mask_in_place |
                             markOopDesc::age_mask_in_place |
                             markOopDesc::epoch_mask_in_place);
    Node* old = transform_later(new (C, 3) AndXNode(mark_node, cmask));
    cast_thread = transform_later(new (C, 2) CastP2XNode(ctrl, thread));
    Node* new_mark = transform_later(new (C, 3) OrXNode(cast_thread, old));
    old_phi->init_req(1, old);
    new_phi->init_req(1, new_mark);

    transform_later(rebiased_region);
    transform_later(old_phi);
    transform_later(new_phi);

    // Try to acquire the bias of the object using an atomic operation.
    // If this fails we will go in to the runtime to revoke the object's bias.
    cas = new (C, 5) StoreXConditionalNode(rebiased_region, mem, adr,
                                           new_phi, old_phi);
    transform_later(cas);
    proj = transform_later( new (C, 1) SCMemProjNode(cas));

    // Get slow path - Failed to CAS.
    not_biased_ctrl = opt_bits_test(rebiased_region, region, 4, cas, 0, 0);
    mem_phi->init_req(4, proj);
    // region->in(4) is set to fast path - the object is rebiased to the current thread.

    // Failed to CAS.
    slow_path  = new (C, 3) RegionNode(3);
    Node *slow_mem = new (C, 3) PhiNode( slow_path, Type::MEMORY, TypeRawPtr::BOTTOM);

    slow_path->init_req(1, not_biased_ctrl); // Capture slow-control
    slow_mem->init_req(1, proj);

    // Call CAS-based locking scheme (FastLock node).

    transform_later(fast_lock_region);
    transform_later(fast_lock_mem_phi);

    // Get slow path - FastLock failed to lock the object.
    ctrl = opt_bits_test(fast_lock_region, region, 2, flock, 0, 0);
    mem_phi->init_req(2, fast_lock_mem_phi);
    // region->in(2) is set to fast path - the object is locked to the current thread.

    slow_path->init_req(2, ctrl); // Capture slow-control
    slow_mem->init_req(2, fast_lock_mem_phi);

    transform_later(slow_path);
    transform_later(slow_mem);
    // Reset lock's memory edge.
    lock->set_req(TypeFunc::Memory, slow_mem);

  } else {
    region  = new (C, 3) RegionNode(3);
    // create a Phi for the memory state
    mem_phi = new (C, 3) PhiNode( region, Type::MEMORY, TypeRawPtr::BOTTOM);

    // Optimize test; set region slot 2
    slow_path = opt_bits_test(ctrl, region, 2, flock, 0, 0);
    mem_phi->init_req(2, mem);
  }
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  // Make slow path call
  CallNode *call = make_slow_call( (CallNode *) lock, OptoRuntime::complete_monitor_enter_Type(), OptoRuntime::complete_monitor_locking_Java(), NULL, slow_path, obj, box );

  extract_call_projections(call);

  // Slow path can only throw asynchronous exceptions, which are always
  // de-opted.  So the compiler thinks the slow-call can never throw an
  // exception.  If it DOES throw an exception we would need the debug
  // info removed first (since if it throws there is no monitor).
  assert ( _ioproj_fallthrough == NULL && _ioproj_catchall == NULL &&
           _memproj_catchall == NULL && _catchallcatchproj == NULL, "Unexpected projection from Lock");

  // Capture slow path
  // disconnect fall-through projection from call and create a new one
  // hook up users of fall-through projection to region
  Node *slow_ctrl = _fallthroughproj->clone();
  transform_later(slow_ctrl);
  _igvn.hash_delete(_fallthroughproj);
  _fallthroughproj->disconnect_inputs(NULL);
  region->init_req(1, slow_ctrl);
  // region inputs are now complete
  transform_later(region);
  _igvn.subsume_node(_fallthroughproj, region);

1871
  Node *memproj = transform_later( new(C, 1) ProjNode(call, TypeFunc::Memory) );
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  mem_phi->init_req(1, memproj );
  transform_later(mem_phi);
1874
  _igvn.hash_delete(_memproj_fallthrough);
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  _igvn.subsume_node(_memproj_fallthrough, mem_phi);
}

//------------------------------expand_unlock_node----------------------
void PhaseMacroExpand::expand_unlock_node(UnlockNode *unlock) {

1881
  Node* ctrl = unlock->in(TypeFunc::Control);
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  Node* mem = unlock->in(TypeFunc::Memory);
  Node* obj = unlock->obj_node();
  Node* box = unlock->box_node();

  // No need for a null check on unlock

  // Make the merge point
1889 1890 1891 1892 1893 1894 1895 1896 1897 1898 1899 1900 1901 1902 1903 1904 1905 1906 1907 1908
  Node *region;
  Node *mem_phi;

  if (UseOptoBiasInlining) {
    // Check for biased locking unlock case, which is a no-op.
    // See the full descrition in MacroAssembler::biased_locking_exit().
    region  = new (C, 4) RegionNode(4);
    // create a Phi for the memory state
    mem_phi = new (C, 4) PhiNode( region, Type::MEMORY, TypeRawPtr::BOTTOM);
    mem_phi->init_req(3, mem);

    Node* mark_node = make_load(ctrl, mem, obj, oopDesc::mark_offset_in_bytes(), TypeX_X, TypeX_X->basic_type());
    ctrl = opt_bits_test(ctrl, region, 3, mark_node,
                         markOopDesc::biased_lock_mask_in_place,
                         markOopDesc::biased_lock_pattern);
  } else {
    region  = new (C, 3) RegionNode(3);
    // create a Phi for the memory state
    mem_phi = new (C, 3) PhiNode( region, Type::MEMORY, TypeRawPtr::BOTTOM);
  }
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  FastUnlockNode *funlock = new (C, 3) FastUnlockNode( ctrl, obj, box );
  funlock = transform_later( funlock )->as_FastUnlock();
  // Optimize test; set region slot 2
1913
  Node *slow_path = opt_bits_test(ctrl, region, 2, funlock, 0, 0);
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  CallNode *call = make_slow_call( (CallNode *) unlock, OptoRuntime::complete_monitor_exit_Type(), CAST_FROM_FN_PTR(address, SharedRuntime::complete_monitor_unlocking_C), "complete_monitor_unlocking_C", slow_path, obj, box );

  extract_call_projections(call);

  assert ( _ioproj_fallthrough == NULL && _ioproj_catchall == NULL &&
           _memproj_catchall == NULL && _catchallcatchproj == NULL, "Unexpected projection from Lock");

  // No exceptions for unlocking
  // Capture slow path
  // disconnect fall-through projection from call and create a new one
  // hook up users of fall-through projection to region
  Node *slow_ctrl = _fallthroughproj->clone();
  transform_later(slow_ctrl);
  _igvn.hash_delete(_fallthroughproj);
  _fallthroughproj->disconnect_inputs(NULL);
  region->init_req(1, slow_ctrl);
  // region inputs are now complete
  transform_later(region);
  _igvn.subsume_node(_fallthroughproj, region);

  Node *memproj = transform_later( new(C, 1) ProjNode(call, TypeFunc::Memory) );
  mem_phi->init_req(1, memproj );
  mem_phi->init_req(2, mem);
  transform_later(mem_phi);
1939
  _igvn.hash_delete(_memproj_fallthrough);
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  _igvn.subsume_node(_memproj_fallthrough, mem_phi);
}

//------------------------------expand_macro_nodes----------------------
//  Returns true if a failure occurred.
bool PhaseMacroExpand::expand_macro_nodes() {
  if (C->macro_count() == 0)
    return false;
1948
  // First, attempt to eliminate locks
1949
  bool progress = true;
1950 1951 1952 1953 1954 1955 1956 1957 1958 1959 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969
  while (progress) {
    progress = false;
    for (int i = C->macro_count(); i > 0; i--) {
      Node * n = C->macro_node(i-1);
      bool success = false;
      debug_only(int old_macro_count = C->macro_count(););
      if (n->is_AbstractLock()) {
        success = eliminate_locking_node(n->as_AbstractLock());
      } else if (n->Opcode() == Op_Opaque1 || n->Opcode() == Op_Opaque2) {
        _igvn.add_users_to_worklist(n);
        _igvn.hash_delete(n);
        _igvn.subsume_node(n, n->in(1));
        success = true;
      }
      assert(success == (C->macro_count() < old_macro_count), "elimination reduces macro count");
      progress = progress || success;
    }
  }
  // Next, attempt to eliminate allocations
  progress = true;
1970 1971 1972 1973 1974 1975 1976 1977 1978 1979 1980 1981 1982
  while (progress) {
    progress = false;
    for (int i = C->macro_count(); i > 0; i--) {
      Node * n = C->macro_node(i-1);
      bool success = false;
      debug_only(int old_macro_count = C->macro_count(););
      switch (n->class_id()) {
      case Node::Class_Allocate:
      case Node::Class_AllocateArray:
        success = eliminate_allocate_node(n->as_Allocate());
        break;
      case Node::Class_Lock:
      case Node::Class_Unlock:
1983
        assert(!n->as_AbstractLock()->is_eliminated(), "sanity");
1984 1985
        break;
      default:
1986
        assert(false, "unknown node type in macro list");
1987 1988 1989 1990 1991 1992 1993 1994
      }
      assert(success == (C->macro_count() < old_macro_count), "elimination reduces macro count");
      progress = progress || success;
    }
  }
  // Make sure expansion will not cause node limit to be exceeded.
  // Worst case is a macro node gets expanded into about 50 nodes.
  // Allow 50% more for optimization.
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  if (C->check_node_count(C->macro_count() * 75, "out of nodes before macro expansion" ) )
    return true;
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  // expand "macro" nodes
  // nodes are removed from the macro list as they are processed
  while (C->macro_count() > 0) {
2001 2002
    int macro_count = C->macro_count();
    Node * n = C->macro_node(macro_count-1);
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    assert(n->is_macro(), "only macro nodes expected here");
    if (_igvn.type(n) == Type::TOP || n->in(0)->is_top() ) {
      // node is unreachable, so don't try to expand it
      C->remove_macro_node(n);
      continue;
    }
    switch (n->class_id()) {
    case Node::Class_Allocate:
      expand_allocate(n->as_Allocate());
      break;
    case Node::Class_AllocateArray:
      expand_allocate_array(n->as_AllocateArray());
      break;
    case Node::Class_Lock:
      expand_lock_node(n->as_Lock());
      break;
    case Node::Class_Unlock:
      expand_unlock_node(n->as_Unlock());
      break;
    default:
      assert(false, "unknown node type in macro list");
    }
2025
    assert(C->macro_count() < macro_count, "must have deleted a node from macro list");
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    if (C->failing())  return true;
  }
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  _igvn.set_delay_transform(false);
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  _igvn.optimize();
  return false;
}