escape.cpp

/*
 * Copyright (c) 2005, 2009, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.
 *
 * This code is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 *
 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
 * or visit www.oracle.com if you need additional information or have any
 * questions.
 *
 */

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

void PointsToNode::add_edge(uint targIdx, PointsToNode::EdgeType et) {
  uint v = (targIdx << EdgeShift) + ((uint) et);
  if (_edges == NULL) {
     Arena *a = Compile::current()->comp_arena();
    _edges = new(a) GrowableArray<uint>(a, INITIAL_EDGE_COUNT, 0, 0);
  }
  _edges->append_if_missing(v);
}

void PointsToNode::remove_edge(uint targIdx, PointsToNode::EdgeType et) {
  uint v = (targIdx << EdgeShift) + ((uint) et);

  _edges->remove(v);
}

#ifndef PRODUCT
static const char *node_type_names[] = {
  "UnknownType",
  "JavaObject",
  "LocalVar",
  "Field"
};

static const char *esc_names[] = {
  "UnknownEscape",
  "NoEscape",
  "ArgEscape",
  "GlobalEscape"
};

static const char *edge_type_suffix[] = {
 "?", // UnknownEdge
 "P", // PointsToEdge
 "D", // DeferredEdge
 "F"  // FieldEdge
};

void PointsToNode::dump(bool print_state) const {
  NodeType nt = node_type();
  tty->print("%s ", node_type_names[(int) nt]);
  if (print_state) {
    EscapeState es = escape_state();
    tty->print("%s %s ", esc_names[(int) es], _scalar_replaceable ? "":"NSR");
  }
  tty->print("[[");
  for (uint i = 0; i < edge_count(); i++) {
    tty->print(" %d%s", edge_target(i), edge_type_suffix[(int) edge_type(i)]);
  }
  tty->print("]]  ");
  if (_node == NULL)
    tty->print_cr("<null>");
  else
    _node->dump();
}
#endif

ConnectionGraph::ConnectionGraph(Compile * C, PhaseIterGVN *igvn) :
  _nodes(C->comp_arena(), C->unique(), C->unique(), PointsToNode()),
  _processed(C->comp_arena()),
  _collecting(true),
  _progress(false),
  _compile(C),
  _igvn(igvn),
  _node_map(C->comp_arena()) {

  _phantom_object = C->top()->_idx,
  add_node(C->top(), PointsToNode::JavaObject, PointsToNode::GlobalEscape,true);

  // Add ConP(#NULL) and ConN(#NULL) nodes.
  Node* oop_null = igvn->zerocon(T_OBJECT);
  _oop_null = oop_null->_idx;
  assert(_oop_null < C->unique(), "should be created already");
  add_node(oop_null, PointsToNode::JavaObject, PointsToNode::NoEscape, true);

  if (UseCompressedOops) {
    Node* noop_null = igvn->zerocon(T_NARROWOOP);
    _noop_null = noop_null->_idx;
    assert(_noop_null < C->unique(), "should be created already");
    add_node(noop_null, PointsToNode::JavaObject, PointsToNode::NoEscape, true);
  }
}

void ConnectionGraph::add_pointsto_edge(uint from_i, uint to_i) {
  PointsToNode *f = ptnode_adr(from_i);
  PointsToNode *t = ptnode_adr(to_i);

  assert(f->node_type() != PointsToNode::UnknownType && t->node_type() != PointsToNode::UnknownType, "node types must be set");
  assert(f->node_type() == PointsToNode::LocalVar || f->node_type() == PointsToNode::Field, "invalid source of PointsTo edge");
  assert(t->node_type() == PointsToNode::JavaObject, "invalid destination of PointsTo edge");
  add_edge(f, to_i, PointsToNode::PointsToEdge);
}

void ConnectionGraph::add_deferred_edge(uint from_i, uint to_i) {
  PointsToNode *f = ptnode_adr(from_i);
  PointsToNode *t = ptnode_adr(to_i);

  assert(f->node_type() != PointsToNode::UnknownType && t->node_type() != PointsToNode::UnknownType, "node types must be set");
  assert(f->node_type() == PointsToNode::LocalVar || f->node_type() == PointsToNode::Field, "invalid source of Deferred edge");
  assert(t->node_type() == PointsToNode::LocalVar || t->node_type() == PointsToNode::Field, "invalid destination of Deferred edge");
  // don't add a self-referential edge, this can occur during removal of
  // deferred edges
  if (from_i != to_i)
    add_edge(f, to_i, PointsToNode::DeferredEdge);
}

int ConnectionGraph::address_offset(Node* adr, PhaseTransform *phase) {
  const Type *adr_type = phase->type(adr);
  if (adr->is_AddP() && adr_type->isa_oopptr() == NULL &&
      adr->in(AddPNode::Address)->is_Proj() &&
      adr->in(AddPNode::Address)->in(0)->is_Allocate()) {
    // We are computing a raw address for a store captured by an Initialize
    // compute an appropriate address type. AddP cases #3 and #5 (see below).
    int offs = (int)phase->find_intptr_t_con(adr->in(AddPNode::Offset), Type::OffsetBot);
    assert(offs != Type::OffsetBot ||
           adr->in(AddPNode::Address)->in(0)->is_AllocateArray(),
           "offset must be a constant or it is initialization of array");
    return offs;
  }
  const TypePtr *t_ptr = adr_type->isa_ptr();
  assert(t_ptr != NULL, "must be a pointer type");
  return t_ptr->offset();
}

void ConnectionGraph::add_field_edge(uint from_i, uint to_i, int offset) {
  PointsToNode *f = ptnode_adr(from_i);
  PointsToNode *t = ptnode_adr(to_i);

  assert(f->node_type() != PointsToNode::UnknownType && t->node_type() != PointsToNode::UnknownType, "node types must be set");
  assert(f->node_type() == PointsToNode::JavaObject, "invalid destination of Field edge");
  assert(t->node_type() == PointsToNode::Field, "invalid destination of Field edge");
  assert (t->offset() == -1 || t->offset() == offset, "conflicting field offsets");
  t->set_offset(offset);

  add_edge(f, to_i, PointsToNode::FieldEdge);
}

void ConnectionGraph::set_escape_state(uint ni, PointsToNode::EscapeState es) {
  PointsToNode *npt = ptnode_adr(ni);
  PointsToNode::EscapeState old_es = npt->escape_state();
  if (es > old_es)
    npt->set_escape_state(es);
}

void ConnectionGraph::add_node(Node *n, PointsToNode::NodeType nt,
                               PointsToNode::EscapeState es, bool done) {
  PointsToNode* ptadr = ptnode_adr(n->_idx);
  ptadr->_node = n;
  ptadr->set_node_type(nt);

  // inline set_escape_state(idx, es);
  PointsToNode::EscapeState old_es = ptadr->escape_state();
  if (es > old_es)
    ptadr->set_escape_state(es);

  if (done)
    _processed.set(n->_idx);
}

PointsToNode::EscapeState ConnectionGraph::escape_state(Node *n) {
  uint idx = n->_idx;
  PointsToNode::EscapeState es;

  // If we are still collecting or there were no non-escaping allocations
  // we don't know the answer yet
  if (_collecting)
    return PointsToNode::UnknownEscape;

  // if the node was created after the escape computation, return
  // UnknownEscape
  if (idx >= nodes_size())
    return PointsToNode::UnknownEscape;

  es = ptnode_adr(idx)->escape_state();

  // if we have already computed a value, return it
  if (es != PointsToNode::UnknownEscape &&
      ptnode_adr(idx)->node_type() == PointsToNode::JavaObject)
    return es;

  // PointsTo() calls n->uncast() which can return a new ideal node.
  if (n->uncast()->_idx >= nodes_size())
    return PointsToNode::UnknownEscape;

  PointsToNode::EscapeState orig_es = es;

  // compute max escape state of anything this node could point to
  VectorSet ptset(Thread::current()->resource_area());
  PointsTo(ptset, n);
  for(VectorSetI i(&ptset); i.test() && es != PointsToNode::GlobalEscape; ++i) {
    uint pt = i.elem;
    PointsToNode::EscapeState pes = ptnode_adr(pt)->escape_state();
    if (pes > es)
      es = pes;
  }
  if (orig_es != es) {
    // cache the computed escape state
    assert(es != PointsToNode::UnknownEscape, "should have computed an escape state");
    ptnode_adr(idx)->set_escape_state(es);
  } // orig_es could be PointsToNode::UnknownEscape
  return es;
}

void ConnectionGraph::PointsTo(VectorSet &ptset, Node * n) {
  VectorSet visited(Thread::current()->resource_area());
  GrowableArray<uint>  worklist;

#ifdef ASSERT
  Node *orig_n = n;
#endif

  n = n->uncast();
  PointsToNode* npt = ptnode_adr(n->_idx);

  // If we have a JavaObject, return just that object
  if (npt->node_type() == PointsToNode::JavaObject) {
    ptset.set(n->_idx);
    return;
  }
#ifdef ASSERT
  if (npt->_node == NULL) {
    if (orig_n != n)
      orig_n->dump();
    n->dump();
    assert(npt->_node != NULL, "unregistered node");
  }
#endif
  worklist.push(n->_idx);
  while(worklist.length() > 0) {
    int ni = worklist.pop();
    if (visited.test_set(ni))
      continue;

    PointsToNode* pn = ptnode_adr(ni);
    // ensure that all inputs of a Phi have been processed
    assert(!_collecting || !pn->_node->is_Phi() || _processed.test(ni),"");

    int edges_processed = 0;
    uint e_cnt = pn->edge_count();
    for (uint e = 0; e < e_cnt; e++) {
      uint etgt = pn->edge_target(e);
      PointsToNode::EdgeType et = pn->edge_type(e);
      if (et == PointsToNode::PointsToEdge) {
        ptset.set(etgt);
        edges_processed++;
      } else if (et == PointsToNode::DeferredEdge) {
        worklist.push(etgt);
        edges_processed++;
      } else {
        assert(false,"neither PointsToEdge or DeferredEdge");
      }
    }
    if (edges_processed == 0) {
      // no deferred or pointsto edges found.  Assume the value was set
      // outside this method.  Add the phantom object to the pointsto set.
      ptset.set(_phantom_object);
    }
  }
}

void ConnectionGraph::remove_deferred(uint ni, GrowableArray<uint>* deferred_edges, VectorSet* visited) {
  // This method is most expensive during ConnectionGraph construction.
  // Reuse vectorSet and an additional growable array for deferred edges.
  deferred_edges->clear();
  visited->Clear();

  visited->set(ni);
  PointsToNode *ptn = ptnode_adr(ni);

  // Mark current edges as visited and move deferred edges to separate array.
  for (uint i = 0; i < ptn->edge_count(); ) {
    uint t = ptn->edge_target(i);
#ifdef ASSERT
    assert(!visited->test_set(t), "expecting no duplications");
#else
    visited->set(t);
#endif
    if (ptn->edge_type(i) == PointsToNode::DeferredEdge) {
      ptn->remove_edge(t, PointsToNode::DeferredEdge);
      deferred_edges->append(t);
    } else {
      i++;
    }
  }
  for (int next = 0; next < deferred_edges->length(); ++next) {
    uint t = deferred_edges->at(next);
    PointsToNode *ptt = ptnode_adr(t);
    uint e_cnt = ptt->edge_count();
    for (uint e = 0; e < e_cnt; e++) {
      uint etgt = ptt->edge_target(e);
      if (visited->test_set(etgt))
        continue;

      PointsToNode::EdgeType et = ptt->edge_type(e);
      if (et == PointsToNode::PointsToEdge) {
        add_pointsto_edge(ni, etgt);
        if(etgt == _phantom_object) {
          // Special case - field set outside (globally escaping).
          ptn->set_escape_state(PointsToNode::GlobalEscape);
        }
      } else if (et == PointsToNode::DeferredEdge) {
        deferred_edges->append(etgt);
      } else {
        assert(false,"invalid connection graph");
      }
    }
  }
}


//  Add an edge to node given by "to_i" from any field of adr_i whose offset
//  matches "offset"  A deferred edge is added if to_i is a LocalVar, and
//  a pointsto edge is added if it is a JavaObject

void ConnectionGraph::add_edge_from_fields(uint adr_i, uint to_i, int offs) {
  PointsToNode* an = ptnode_adr(adr_i);
  PointsToNode* to = ptnode_adr(to_i);
  bool deferred = (to->node_type() == PointsToNode::LocalVar);

  for (uint fe = 0; fe < an->edge_count(); fe++) {
    assert(an->edge_type(fe) == PointsToNode::FieldEdge, "expecting a field edge");
    int fi = an->edge_target(fe);
    PointsToNode* pf = ptnode_adr(fi);
    int po = pf->offset();
    if (po == offs || po == Type::OffsetBot || offs == Type::OffsetBot) {
      if (deferred)
        add_deferred_edge(fi, to_i);
      else
        add_pointsto_edge(fi, to_i);
    }
  }
}

// Add a deferred  edge from node given by "from_i" to any field of adr_i
// whose offset matches "offset".
void ConnectionGraph::add_deferred_edge_to_fields(uint from_i, uint adr_i, int offs) {
  PointsToNode* an = ptnode_adr(adr_i);
  for (uint fe = 0; fe < an->edge_count(); fe++) {
    assert(an->edge_type(fe) == PointsToNode::FieldEdge, "expecting a field edge");
    int fi = an->edge_target(fe);
    PointsToNode* pf = ptnode_adr(fi);
    int po = pf->offset();
    if (pf->edge_count() == 0) {
      // we have not seen any stores to this field, assume it was set outside this method
      add_pointsto_edge(fi, _phantom_object);
    }
    if (po == offs || po == Type::OffsetBot || offs == Type::OffsetBot) {
      add_deferred_edge(from_i, fi);
    }
  }
}

// Helper functions

static Node* get_addp_base(Node *addp) {
  assert(addp->is_AddP(), "must be AddP");
  //
  // AddP cases for Base and Address inputs:
  // case #1. Direct object's field reference:
  //     Allocate
  //       |
  //     Proj #5 ( oop result )
  //       |
  //     CheckCastPP (cast to instance type)
  //      | |
  //     AddP  ( base == address )
  //
  // case #2. Indirect object's field reference:
  //      Phi
  //       |
  //     CastPP (cast to instance type)
  //      | |
  //     AddP  ( base == address )
  //
  // case #3. Raw object's field reference for Initialize node:
  //      Allocate
  //        |
  //      Proj #5 ( oop result )
  //  top   |
  //     \  |
  //     AddP  ( base == top )
  //
  // case #4. Array's element reference:
  //   {CheckCastPP | CastPP}
  //     |  | |
  //     |  AddP ( array's element offset )
  //     |  |
  //     AddP ( array's offset )
  //
  // case #5. Raw object's field reference for arraycopy stub call:
  //          The inline_native_clone() case when the arraycopy stub is called
  //          after the allocation before Initialize and CheckCastPP nodes.
  //      Allocate
  //        |
  //      Proj #5 ( oop result )
  //       | |
  //       AddP  ( base == address )
  //
  // case #6. Constant Pool, ThreadLocal, CastX2P or
  //          Raw object's field reference:
  //      {ConP, ThreadLocal, CastX2P, raw Load}
  //  top   |
  //     \  |
  //     AddP  ( base == top )
  //
  // case #7. Klass's field reference.
  //      LoadKlass
  //       | |
  //       AddP  ( base == address )
  //
  // case #8. narrow Klass's field reference.
  //      LoadNKlass
  //       |
  //      DecodeN
  //       | |
  //       AddP  ( base == address )
  //
  Node *base = addp->in(AddPNode::Base)->uncast();
  if (base->is_top()) { // The AddP case #3 and #6.
    base = addp->in(AddPNode::Address)->uncast();
    while (base->is_AddP()) {
      // Case #6 (unsafe access) may have several chained AddP nodes.
      assert(base->in(AddPNode::Base)->is_top(), "expected unsafe access address only");
      base = base->in(AddPNode::Address)->uncast();
    }
    assert(base->Opcode() == Op_ConP || base->Opcode() == Op_ThreadLocal ||
           base->Opcode() == Op_CastX2P || base->is_DecodeN() ||
           (base->is_Mem() && base->bottom_type() == TypeRawPtr::NOTNULL) ||
           (base->is_Proj() && base->in(0)->is_Allocate()), "sanity");
  }
  return base;
}

static Node* find_second_addp(Node* addp, Node* n) {
  assert(addp->is_AddP() && addp->outcnt() > 0, "Don't process dead nodes");

  Node* addp2 = addp->raw_out(0);
  if (addp->outcnt() == 1 && addp2->is_AddP() &&
      addp2->in(AddPNode::Base) == n &&
      addp2->in(AddPNode::Address) == addp) {

    assert(addp->in(AddPNode::Base) == n, "expecting the same base");
    //
    // Find array's offset to push it on worklist first and
    // as result process an array's element offset first (pushed second)
    // to avoid CastPP for the array's offset.
    // Otherwise the inserted CastPP (LocalVar) will point to what
    // the AddP (Field) points to. Which would be wrong since
    // the algorithm expects the CastPP has the same point as
    // as AddP's base CheckCastPP (LocalVar).
    //
    //    ArrayAllocation
    //     |
    //    CheckCastPP
    //     |
    //    memProj (from ArrayAllocation CheckCastPP)
    //     |  ||
    //     |  ||   Int (element index)
    //     |  ||    |   ConI (log(element size))
    //     |  ||    |   /
    //     |  ||   LShift
    //     |  ||  /
    //     |  AddP (array's element offset)
    //     |  |
    //     |  | ConI (array's offset: #12(32-bits) or #24(64-bits))
    //     | / /
    //     AddP (array's offset)
    //      |
    //     Load/Store (memory operation on array's element)
    //
    return addp2;
  }
  return NULL;
}

//
// Adjust the type and inputs of an AddP which computes the
// address of a field of an instance
//
bool ConnectionGraph::split_AddP(Node *addp, Node *base,  PhaseGVN  *igvn) {
  const TypeOopPtr *base_t = igvn->type(base)->isa_oopptr();
  assert(base_t != NULL && base_t->is_known_instance(), "expecting instance oopptr");
  const TypeOopPtr *t = igvn->type(addp)->isa_oopptr();
  if (t == NULL) {
    // We are computing a raw address for a store captured by an Initialize
    // compute an appropriate address type (cases #3 and #5).
    assert(igvn->type(addp) == TypeRawPtr::NOTNULL, "must be raw pointer");
    assert(addp->in(AddPNode::Address)->is_Proj(), "base of raw address must be result projection from allocation");
    intptr_t offs = (int)igvn->find_intptr_t_con(addp->in(AddPNode::Offset), Type::OffsetBot);
    assert(offs != Type::OffsetBot, "offset must be a constant");
    t = base_t->add_offset(offs)->is_oopptr();
  }
  int inst_id =  base_t->instance_id();
  assert(!t->is_known_instance() || t->instance_id() == inst_id,
                             "old type must be non-instance or match new type");

  // The type 't' could be subclass of 'base_t'.
  // As result t->offset() could be large then base_t's size and it will
  // cause the failure in add_offset() with narrow oops since TypeOopPtr()
  // constructor verifies correctness of the offset.
  //
  // It could happened on subclass's branch (from the type profiling
  // inlining) which was not eliminated during parsing since the exactness
  // of the allocation type was not propagated to the subclass type check.
  //
  // Or the type 't' could be not related to 'base_t' at all.
  // It could happened when CHA type is different from MDO type on a dead path
  // (for example, from instanceof check) which is not collapsed during parsing.
  //
  // Do nothing for such AddP node and don't process its users since
  // this code branch will go away.
  //
  if (!t->is_known_instance() &&
      !base_t->klass()->is_subtype_of(t->klass())) {
     return false; // bail out
  }

  const TypeOopPtr *tinst = base_t->add_offset(t->offset())->is_oopptr();
  // Do NOT remove the next line: ensure a new alias index is allocated
  // for the instance type. Note: C++ will not remove it since the call
  // has side effect.
  int alias_idx = _compile->get_alias_index(tinst);
  igvn->set_type(addp, tinst);
  // record the allocation in the node map
  assert(ptnode_adr(addp->_idx)->_node != NULL, "should be registered");
  set_map(addp->_idx, get_map(base->_idx));

  // Set addp's Base and Address to 'base'.
  Node *abase = addp->in(AddPNode::Base);
  Node *adr   = addp->in(AddPNode::Address);
  if (adr->is_Proj() && adr->in(0)->is_Allocate() &&
      adr->in(0)->_idx == (uint)inst_id) {
    // Skip AddP cases #3 and #5.
  } else {
    assert(!abase->is_top(), "sanity"); // AddP case #3
    if (abase != base) {
      igvn->hash_delete(addp);
      addp->set_req(AddPNode::Base, base);
      if (abase == adr) {
        addp->set_req(AddPNode::Address, base);
      } else {
        // AddP case #4 (adr is array's element offset AddP node)
#ifdef ASSERT
        const TypeOopPtr *atype = igvn->type(adr)->isa_oopptr();
        assert(adr->is_AddP() && atype != NULL &&
               atype->instance_id() == inst_id, "array's element offset should be processed first");
#endif
      }
      igvn->hash_insert(addp);
    }
  }
  // Put on IGVN worklist since at least addp's type was changed above.
  record_for_optimizer(addp);
  return true;
}

//
// Create a new version of orig_phi if necessary. Returns either the newly
// created phi or an existing phi.  Sets create_new to indicate wheter  a new
// phi was created.  Cache the last newly created phi in the node map.
//
PhiNode *ConnectionGraph::create_split_phi(PhiNode *orig_phi, int alias_idx, GrowableArray<PhiNode *>  &orig_phi_worklist, PhaseGVN  *igvn, bool &new_created) {
  Compile *C = _compile;
  new_created = false;
  int phi_alias_idx = C->get_alias_index(orig_phi->adr_type());
  // nothing to do if orig_phi is bottom memory or matches alias_idx
  if (phi_alias_idx == alias_idx) {
    return orig_phi;
  }
  // Have we recently created a Phi for this alias index?
  PhiNode *result = get_map_phi(orig_phi->_idx);
  if (result != NULL && C->get_alias_index(result->adr_type()) == alias_idx) {
    return result;
  }
  // Previous check may fail when the same wide memory Phi was split into Phis
  // for different memory slices. Search all Phis for this region.
  if (result != NULL) {
    Node* region = orig_phi->in(0);
    for (DUIterator_Fast imax, i = region->fast_outs(imax); i < imax; i++) {
      Node* phi = region->fast_out(i);
      if (phi->is_Phi() &&
          C->get_alias_index(phi->as_Phi()->adr_type()) == alias_idx) {
        assert(phi->_idx >= nodes_size(), "only new Phi per instance memory slice");
        return phi->as_Phi();
      }
    }
  }
  if ((int)C->unique() + 2*NodeLimitFudgeFactor > MaxNodeLimit) {
    if (C->do_escape_analysis() == true && !C->failing()) {
      // Retry compilation without escape analysis.
      // If this is the first failure, the sentinel string will "stick"
      // to the Compile object, and the C2Compiler will see it and retry.
      C->record_failure(C2Compiler::retry_no_escape_analysis());
    }
    return NULL;
  }
  orig_phi_worklist.append_if_missing(orig_phi);
  const TypePtr *atype = C->get_adr_type(alias_idx);
  result = PhiNode::make(orig_phi->in(0), NULL, Type::MEMORY, atype);
  C->copy_node_notes_to(result, orig_phi);
  igvn->set_type(result, result->bottom_type());
  record_for_optimizer(result);

  debug_only(Node* pn = ptnode_adr(orig_phi->_idx)->_node;)
  assert(pn == NULL || pn == orig_phi, "wrong node");
  set_map(orig_phi->_idx, result);
  ptnode_adr(orig_phi->_idx)->_node = orig_phi;

  new_created = true;
  return result;
}

//
// Return a new version  of Memory Phi "orig_phi" with the inputs having the
// specified alias index.
//
PhiNode *ConnectionGraph::split_memory_phi(PhiNode *orig_phi, int alias_idx, GrowableArray<PhiNode *>  &orig_phi_worklist, PhaseGVN  *igvn) {

  assert(alias_idx != Compile::AliasIdxBot, "can't split out bottom memory");
  Compile *C = _compile;
  bool new_phi_created;
  PhiNode *result = create_split_phi(orig_phi, alias_idx, orig_phi_worklist, igvn, new_phi_created);
  if (!new_phi_created) {
    return result;
  }

  GrowableArray<PhiNode *>  phi_list;
  GrowableArray<uint>  cur_input;

  PhiNode *phi = orig_phi;
  uint idx = 1;
  bool finished = false;
  while(!finished) {
    while (idx < phi->req()) {
      Node *mem = find_inst_mem(phi->in(idx), alias_idx, orig_phi_worklist, igvn);
      if (mem != NULL && mem->is_Phi()) {
        PhiNode *newphi = create_split_phi(mem->as_Phi(), alias_idx, orig_phi_worklist, igvn, new_phi_created);
        if (new_phi_created) {
          // found an phi for which we created a new split, push current one on worklist and begin
          // processing new one
          phi_list.push(phi);
          cur_input.push(idx);
          phi = mem->as_Phi();
          result = newphi;
          idx = 1;
          continue;
        } else {
          mem = newphi;
        }
      }
      if (C->failing()) {
        return NULL;
      }
      result->set_req(idx++, mem);
    }
#ifdef ASSERT
    // verify that the new Phi has an input for each input of the original
    assert( phi->req() == result->req(), "must have same number of inputs.");
    assert( result->in(0) != NULL && result->in(0) == phi->in(0), "regions must match");
#endif
    // Check if all new phi's inputs have specified alias index.
    // Otherwise use old phi.
    for (uint i = 1; i < phi->req(); i++) {
      Node* in = result->in(i);
      assert((phi->in(i) == NULL) == (in == NULL), "inputs must correspond.");
    }
    // we have finished processing a Phi, see if there are any more to do
    finished = (phi_list.length() == 0 );
    if (!finished) {
      phi = phi_list.pop();
      idx = cur_input.pop();
      PhiNode *prev_result = get_map_phi(phi->_idx);
      prev_result->set_req(idx++, result);
      result = prev_result;
    }
  }
  return result;
}


//
// The next methods are derived from methods in MemNode.
//
static Node *step_through_mergemem(MergeMemNode *mmem, int alias_idx, const TypeOopPtr *toop) {
  Node *mem = mmem;
  // TypeOopPtr::NOTNULL+any is an OOP with unknown offset - generally
  // means an array I have not precisely typed yet.  Do not do any
  // alias stuff with it any time soon.
  if( toop->base() != Type::AnyPtr &&
      !(toop->klass() != NULL &&
        toop->klass()->is_java_lang_Object() &&
        toop->offset() == Type::OffsetBot) ) {
    mem = mmem->memory_at(alias_idx);
    // Update input if it is progress over what we have now
  }
  return mem;
}

//
// Move memory users to their memory slices.
//
void ConnectionGraph::move_inst_mem(Node* n, GrowableArray<PhiNode *>  &orig_phis, PhaseGVN *igvn) {
  Compile* C = _compile;

  const TypePtr* tp = igvn->type(n->in(MemNode::Address))->isa_ptr();
  assert(tp != NULL, "ptr type");
  int alias_idx = C->get_alias_index(tp);
  int general_idx = C->get_general_index(alias_idx);

  // Move users first
  for (DUIterator_Fast imax, i = n->fast_outs(imax); i < imax; i++) {
    Node* use = n->fast_out(i);
    if (use->is_MergeMem()) {
      MergeMemNode* mmem = use->as_MergeMem();
      assert(n == mmem->memory_at(alias_idx), "should be on instance memory slice");
      if (n != mmem->memory_at(general_idx) || alias_idx == general_idx) {
        continue; // Nothing to do
      }
      // Replace previous general reference to mem node.
      uint orig_uniq = C->unique();
      Node* m = find_inst_mem(n, general_idx, orig_phis, igvn);
      assert(orig_uniq == C->unique(), "no new nodes");
      mmem->set_memory_at(general_idx, m);
      --imax;
      --i;
    } else if (use->is_MemBar()) {
      assert(!use->is_Initialize(), "initializing stores should not be moved");
      if (use->req() > MemBarNode::Precedent &&
          use->in(MemBarNode::Precedent) == n) {
        // Don't move related membars.
        record_for_optimizer(use);
        continue;
      }
      tp = use->as_MemBar()->adr_type()->isa_ptr();
      if (tp != NULL && C->get_alias_index(tp) == alias_idx ||
          alias_idx == general_idx) {
        continue; // Nothing to do
      }
      // Move to general memory slice.
      uint orig_uniq = C->unique();
      Node* m = find_inst_mem(n, general_idx, orig_phis, igvn);
      assert(orig_uniq == C->unique(), "no new nodes");
      igvn->hash_delete(use);
      imax -= use->replace_edge(n, m);
      igvn->hash_insert(use);
      record_for_optimizer(use);
      --i;
#ifdef ASSERT
    } else if (use->is_Mem()) {
      if (use->Opcode() == Op_StoreCM && use->in(MemNode::OopStore) == n) {
        // Don't move related cardmark.
        continue;
      }
      // Memory nodes should have new memory input.
      tp = igvn->type(use->in(MemNode::Address))->isa_ptr();
      assert(tp != NULL, "ptr type");
      int idx = C->get_alias_index(tp);
      assert(get_map(use->_idx) != NULL || idx == alias_idx,
             "Following memory nodes should have new memory input or be on the same memory slice");
    } else if (use->is_Phi()) {
      // Phi nodes should be split and moved already.
      tp = use->as_Phi()->adr_type()->isa_ptr();
      assert(tp != NULL, "ptr type");
      int idx = C->get_alias_index(tp);
      assert(idx == alias_idx, "Following Phi nodes should be on the same memory slice");
    } else {
      use->dump();
      assert(false, "should not be here");
#endif
    }
  }
}

//
// Search memory chain of "mem" to find a MemNode whose address
// is the specified alias index.
//
Node* ConnectionGraph::find_inst_mem(Node *orig_mem, int alias_idx, GrowableArray<PhiNode *>  &orig_phis, PhaseGVN *phase) {
  if (orig_mem == NULL)
    return orig_mem;
  Compile* C = phase->C;
  const TypeOopPtr *toop = C->get_adr_type(alias_idx)->isa_oopptr();
  bool is_instance = (toop != NULL) && toop->is_known_instance();
  Node *start_mem = C->start()->proj_out(TypeFunc::Memory);
  Node *prev = NULL;
  Node *result = orig_mem;
  while (prev != result) {
    prev = result;
    if (result == start_mem)
      break;  // hit one of our sentinels
    if (result->is_Mem()) {
      const Type *at = phase->type(result->in(MemNode::Address));
      if (at != Type::TOP) {
        assert (at->isa_ptr() != NULL, "pointer type required.");
        int idx = C->get_alias_index(at->is_ptr());
        if (idx == alias_idx)
          break;
      }
      result = result->in(MemNode::Memory);
    }
    if (!is_instance)
      continue;  // don't search further for non-instance types
    // skip over a call which does not affect this memory slice
    if (result->is_Proj() && result->as_Proj()->_con == TypeFunc::Memory) {
      Node *proj_in = result->in(0);
      if (proj_in->is_Allocate() && proj_in->_idx == (uint)toop->instance_id()) {
        break;  // hit one of our sentinels
      } else if (proj_in->is_Call()) {
        CallNode *call = proj_in->as_Call();
        if (!call->may_modify(toop, phase)) {
          result = call->in(TypeFunc::Memory);
        }
      } else if (proj_in->is_Initialize()) {
        AllocateNode* alloc = proj_in->as_Initialize()->allocation();
        // Stop if this is the initialization for the object instance which
        // which contains this memory slice, otherwise skip over it.
        if (alloc == NULL || alloc->_idx != (uint)toop->instance_id()) {
          result = proj_in->in(TypeFunc::Memory);
        }
      } else if (proj_in->is_MemBar()) {
        result = proj_in->in(TypeFunc::Memory);
      }
    } else if (result->is_MergeMem()) {
      MergeMemNode *mmem = result->as_MergeMem();
      result = step_through_mergemem(mmem, alias_idx, toop);
      if (result == mmem->base_memory()) {
        // Didn't find instance memory, search through general slice recursively.
        result = mmem->memory_at(C->get_general_index(alias_idx));
        result = find_inst_mem(result, alias_idx, orig_phis, phase);
        if (C->failing()) {
          return NULL;
        }
        mmem->set_memory_at(alias_idx, result);
      }
    } else if (result->is_Phi() &&
               C->get_alias_index(result->as_Phi()->adr_type()) != alias_idx) {
      Node *un = result->as_Phi()->unique_input(phase);
      if (un != NULL) {
        orig_phis.append_if_missing(result->as_Phi());
        result = un;
      } else {
        break;
      }
    } else if (result->is_ClearArray()) {
      if (!ClearArrayNode::step_through(&result, (uint)toop->instance_id(), phase)) {
        // Can not bypass initialization of the instance
        // we are looking for.
        break;
      }
      // Otherwise skip it (the call updated 'result' value).
    } else if (result->Opcode() == Op_SCMemProj) {
      assert(result->in(0)->is_LoadStore(), "sanity");
      const Type *at = phase->type(result->in(0)->in(MemNode::Address));
      if (at != Type::TOP) {
        assert (at->isa_ptr() != NULL, "pointer type required.");
        int idx = C->get_alias_index(at->is_ptr());
        assert(idx != alias_idx, "Object is not scalar replaceable if a LoadStore node access its field");
        break;
      }
      result = result->in(0)->in(MemNode::Memory);
    }
  }
  if (result->is_Phi()) {
    PhiNode *mphi = result->as_Phi();
    assert(mphi->bottom_type() == Type::MEMORY, "memory phi required");
    const TypePtr *t = mphi->adr_type();
    if (C->get_alias_index(t) != alias_idx) {
      // Create a new Phi with the specified alias index type.
      result = split_memory_phi(mphi, alias_idx, orig_phis, phase);
    } else if (!is_instance) {
      // Push all non-instance Phis on the orig_phis worklist to update inputs
      // during Phase 4 if needed.
      orig_phis.append_if_missing(mphi);
    }
  }
  // the result is either MemNode, PhiNode, InitializeNode.
  return result;
}

//
//  Convert the types of unescaped object to instance types where possible,
//  propagate the new type information through the graph, and update memory
//  edges and MergeMem inputs to reflect the new type.
//
//  We start with allocations (and calls which may be allocations)  on alloc_worklist.
//  The processing is done in 4 phases:
//
//  Phase 1:  Process possible allocations from alloc_worklist.  Create instance
//            types for the CheckCastPP for allocations where possible.
//            Propagate the the new types through users as follows:
//               casts and Phi:  push users on alloc_worklist
//               AddP:  cast Base and Address inputs to the instance type
//                      push any AddP users on alloc_worklist and push any memnode
//                      users onto memnode_worklist.
//  Phase 2:  Process MemNode's from memnode_worklist. compute new address type and
//            search the Memory chain for a store with the appropriate type
//            address type.  If a Phi is found, create a new version with
//            the appropriate memory slices from each of the Phi inputs.
//            For stores, process the users as follows:
//               MemNode:  push on memnode_worklist
//               MergeMem: push on mergemem_worklist
//  Phase 3:  Process MergeMem nodes from mergemem_worklist.  Walk each memory slice
//            moving the first node encountered of each  instance type to the
//            the input corresponding to its alias index.
//            appropriate memory slice.
//  Phase 4:  Update the inputs of non-instance memory Phis and the Memory input of memnodes.
//
// In the following example, the CheckCastPP nodes are the cast of allocation
// results and the allocation of node 29 is unescaped and eligible to be an
// instance type.
//
// We start with:
//
//     7 Parm #memory
//    10  ConI  "12"
//    19  CheckCastPP   "Foo"
//    20  AddP  _ 19 19 10  Foo+12  alias_index=4
//    29  CheckCastPP   "Foo"
//    30  AddP  _ 29 29 10  Foo+12  alias_index=4
//
//    40  StoreP  25   7  20   ... alias_index=4
//    50  StoreP  35  40  30   ... alias_index=4
//    60  StoreP  45  50  20   ... alias_index=4
//    70  LoadP    _  60  30   ... alias_index=4
//    80  Phi     75  50  60   Memory alias_index=4
//    90  LoadP    _  80  30   ... alias_index=4
//   100  LoadP    _  80  20   ... alias_index=4
//
//
// Phase 1 creates an instance type for node 29 assigning it an instance id of 24
// and creating a new alias index for node 30.  This gives:
//
//     7 Parm #memory
//    10  ConI  "12"
//    19  CheckCastPP   "Foo"
//    20  AddP  _ 19 19 10  Foo+12  alias_index=4
//    29  CheckCastPP   "Foo"  iid=24
//    30  AddP  _ 29 29 10  Foo+12  alias_index=6  iid=24
//
//    40  StoreP  25   7  20   ... alias_index=4
//    50  StoreP  35  40  30   ... alias_index=6
//    60  StoreP  45  50  20   ... alias_index=4
//    70  LoadP    _  60  30   ... alias_index=6
//    80  Phi     75  50  60   Memory alias_index=4
//    90  LoadP    _  80  30   ... alias_index=6
//   100  LoadP    _  80  20   ... alias_index=4
//
// In phase 2, new memory inputs are computed for the loads and stores,
// And a new version of the phi is created.  In phase 4, the inputs to
// node 80 are updated and then the memory nodes are updated with the
// values computed in phase 2.  This results in:
//
//     7 Parm #memory
//    10  ConI  "12"
//    19  CheckCastPP   "Foo"
//    20  AddP  _ 19 19 10  Foo+12  alias_index=4
//    29  CheckCastPP   "Foo"  iid=24
//    30  AddP  _ 29 29 10  Foo+12  alias_index=6  iid=24
//
//    40  StoreP  25  7   20   ... alias_index=4
//    50  StoreP  35  7   30   ... alias_index=6
//    60  StoreP  45  40  20   ... alias_index=4
//    70  LoadP    _  50  30   ... alias_index=6
//    80  Phi     75  40  60   Memory alias_index=4
//   120  Phi     75  50  50   Memory alias_index=6
//    90  LoadP    _ 120  30   ... alias_index=6
//   100  LoadP    _  80  20   ... alias_index=4
//
void ConnectionGraph::split_unique_types(GrowableArray<Node *>  &alloc_worklist) {
  GrowableArray<Node *>  memnode_worklist;
  GrowableArray<PhiNode *>  orig_phis;

  PhaseIterGVN  *igvn = _igvn;
  uint new_index_start = (uint) _compile->num_alias_types();
  Arena* arena = Thread::current()->resource_area();
  VectorSet visited(arena);
  VectorSet ptset(arena);


  //  Phase 1:  Process possible allocations from alloc_worklist.
  //  Create instance types for the CheckCastPP for allocations where possible.
  //
  // (Note: don't forget to change the order of the second AddP node on
  //  the alloc_worklist if the order of the worklist processing is changed,
  //  see the comment in find_second_addp().)
  //
  while (alloc_worklist.length() != 0) {
    Node *n = alloc_worklist.pop();
    uint ni = n->_idx;
    const TypeOopPtr* tinst = NULL;
    if (n->is_Call()) {
      CallNode *alloc = n->as_Call();
      // copy escape information to call node
      PointsToNode* ptn = ptnode_adr(alloc->_idx);
      PointsToNode::EscapeState es = escape_state(alloc);
      // We have an allocation or call which returns a Java object,
      // see if it is unescaped.
      if (es != PointsToNode::NoEscape || !ptn->_scalar_replaceable)
        continue;

      // Find CheckCastPP for the allocate or for the return value of a call
      n = alloc->result_cast();
      if (n == NULL) {            // No uses except Initialize node
        if (alloc->is_Allocate()) {
          // Set the scalar_replaceable flag for allocation
          // so it could be eliminated if it has no uses.
          alloc->as_Allocate()->_is_scalar_replaceable = true;
        }
        continue;
      }
      if (!n->is_CheckCastPP()) { // not unique CheckCastPP.
        assert(!alloc->is_Allocate(), "allocation should have unique type");
        continue;
      }

      // The inline code for Object.clone() casts the allocation result to
      // java.lang.Object and then to the actual type of the allocated
      // object. Detect this case and use the second cast.
      // Also detect j.l.reflect.Array.newInstance(jobject, jint) case when
      // the allocation result is cast to java.lang.Object and then
      // to the actual Array type.
      if (alloc->is_Allocate() && n->as_Type()->type() == TypeInstPtr::NOTNULL
          && (alloc->is_AllocateArray() ||
              igvn->type(alloc->in(AllocateNode::KlassNode)) != TypeKlassPtr::OBJECT)) {
        Node *cast2 = NULL;
        for (DUIterator_Fast imax, i = n->fast_outs(imax); i < imax; i++) {
          Node *use = n->fast_out(i);
          if (use->is_CheckCastPP()) {
            cast2 = use;
            break;
          }
        }
        if (cast2 != NULL) {
          n = cast2;
        } else {
          // Non-scalar replaceable if the allocation type is unknown statically
          // (reflection allocation), the object can't be restored during
          // deoptimization without precise type.
          continue;
        }
      }
      if (alloc->is_Allocate()) {
        // Set the scalar_replaceable flag for allocation
        // so it could be eliminated.
        alloc->as_Allocate()->_is_scalar_replaceable = true;
      }
      set_escape_state(n->_idx, es);
      // in order for an object to be scalar-replaceable, it must be:
      //   - a direct allocation (not a call returning an object)
      //   - non-escaping
      //   - eligible to be a unique type
      //   - not determined to be ineligible by escape analysis
      assert(ptnode_adr(alloc->_idx)->_node != NULL &&
             ptnode_adr(n->_idx)->_node != NULL, "should be registered");
      set_map(alloc->_idx, n);
      set_map(n->_idx, alloc);
      const TypeOopPtr *t = igvn->type(n)->isa_oopptr();
      if (t == NULL)
        continue;  // not a TypeInstPtr
      tinst = t->cast_to_exactness(true)->is_oopptr()->cast_to_instance_id(ni);
      igvn->hash_delete(n);
      igvn->set_type(n,  tinst);
      n->raise_bottom_type(tinst);
      igvn->hash_insert(n);
      record_for_optimizer(n);
      if (alloc->is_Allocate() && ptn->_scalar_replaceable &&
          (t->isa_instptr() || t->isa_aryptr())) {

        // First, put on the worklist all Field edges from Connection Graph
        // which is more accurate then putting immediate users from Ideal Graph.
        for (uint e = 0; e < ptn->edge_count(); e++) {
          Node *use = ptnode_adr(ptn->edge_target(e))->_node;
          assert(ptn->edge_type(e) == PointsToNode::FieldEdge && use->is_AddP(),
                 "only AddP nodes are Field edges in CG");
          if (use->outcnt() > 0) { // Don't process dead nodes
            Node* addp2 = find_second_addp(use, use->in(AddPNode::Base));
            if (addp2 != NULL) {
              assert(alloc->is_AllocateArray(),"array allocation was expected");
              alloc_worklist.append_if_missing(addp2);
            }
            alloc_worklist.append_if_missing(use);
          }
        }

        // An allocation may have an Initialize which has raw stores. Scan
        // the users of the raw allocation result and push AddP users
        // on alloc_worklist.
        Node *raw_result = alloc->proj_out(TypeFunc::Parms);
        assert (raw_result != NULL, "must have an allocation result");
        for (DUIterator_Fast imax, i = raw_result->fast_outs(imax); i < imax; i++) {
          Node *use = raw_result->fast_out(i);
          if (use->is_AddP() && use->outcnt() > 0) { // Don't process dead nodes
            Node* addp2 = find_second_addp(use, raw_result);
            if (addp2 != NULL) {
              assert(alloc->is_AllocateArray(),"array allocation was expected");
              alloc_worklist.append_if_missing(addp2);
            }
            alloc_worklist.append_if_missing(use);
          } else if (use->is_MemBar()) {
            memnode_worklist.append_if_missing(use);
          }
        }
      }
    } else if (n->is_AddP()) {
      ptset.Clear();
      PointsTo(ptset, get_addp_base(n));
      assert(ptset.Size() == 1, "AddP address is unique");
      uint elem = ptset.getelem(); // Allocation node's index
      if (elem == _phantom_object) {
        assert(false, "escaped allocation");
        continue; // Assume the value was set outside this method.
      }
      Node *base = get_map(elem);  // CheckCastPP node
      if (!split_AddP(n, base, igvn)) continue; // wrong type from dead path
      tinst = igvn->type(base)->isa_oopptr();
    } else if (n->is_Phi() ||
               n->is_CheckCastPP() ||
               n->is_EncodeP() ||
               n->is_DecodeN() ||
               (n->is_ConstraintCast() && n->Opcode() == Op_CastPP)) {
      if (visited.test_set(n->_idx)) {
        assert(n->is_Phi(), "loops only through Phi's");
        continue;  // already processed
      }
      ptset.Clear();
      PointsTo(ptset, n);
      if (ptset.Size() == 1) {
        uint elem = ptset.getelem(); // Allocation node's index
        if (elem == _phantom_object) {
          assert(false, "escaped allocation");
          continue; // Assume the value was set outside this method.
        }
        Node *val = get_map(elem);   // CheckCastPP node
        TypeNode *tn = n->as_Type();
        tinst = igvn->type(val)->isa_oopptr();
        assert(tinst != NULL && tinst->is_known_instance() &&
               (uint)tinst->instance_id() == elem , "instance type expected.");

        const Type *tn_type = igvn->type(tn);
        const TypeOopPtr *tn_t;
        if (tn_type->isa_narrowoop()) {
          tn_t = tn_type->make_ptr()->isa_oopptr();
        } else {
          tn_t = tn_type->isa_oopptr();
        }

        if (tn_t != NULL && tinst->klass()->is_subtype_of(tn_t->klass())) {
          if (tn_type->isa_narrowoop()) {
            tn_type = tinst->make_narrowoop();
          } else {
            tn_type = tinst;
          }
          igvn->hash_delete(tn);
          igvn->set_type(tn, tn_type);
          tn->set_type(tn_type);
          igvn->hash_insert(tn);
          record_for_optimizer(n);
        } else {
          assert(tn_type == TypePtr::NULL_PTR ||
                 tn_t != NULL && !tinst->klass()->is_subtype_of(tn_t->klass()),
                 "unexpected type");
          continue; // Skip dead path with different type
        }
      }
    } else {
      debug_only(n->dump();)
      assert(false, "EA: unexpected node");
      continue;
    }
    // push allocation's users on appropriate worklist
    for (DUIterator_Fast imax, i = n->fast_outs(imax); i < imax; i++) {
      Node *use = n->fast_out(i);
      if(use->is_Mem() && use->in(MemNode::Address) == n) {
        // Load/store to instance's field
        memnode_worklist.append_if_missing(use);
      } else if (use->is_MemBar()) {
        memnode_worklist.append_if_missing(use);
      } else if (use->is_AddP() && use->outcnt() > 0) { // No dead nodes
        Node* addp2 = find_second_addp(use, n);
        if (addp2 != NULL) {
          alloc_worklist.append_if_missing(addp2);
        }
        alloc_worklist.append_if_missing(use);
      } else if (use->is_Phi() ||
                 use->is_CheckCastPP() ||
                 use->is_EncodeP() ||
                 use->is_DecodeN() ||
                 (use->is_ConstraintCast() && use->Opcode() == Op_CastPP)) {
        alloc_worklist.append_if_missing(use);
#ifdef ASSERT
      } else if (use->is_Mem()) {
        assert(use->in(MemNode::Address) != n, "EA: missing allocation reference path");
      } else if (use->is_MergeMem()) {
        assert(_mergemem_worklist.contains(use->as_MergeMem()), "EA: missing MergeMem node in the worklist");
      } else if (use->is_SafePoint()) {
        // Look for MergeMem nodes for calls which reference unique allocation
        // (through CheckCastPP nodes) even for debug info.
        Node* m = use->in(TypeFunc::Memory);
        if (m->is_MergeMem()) {
          assert(_mergemem_worklist.contains(m->as_MergeMem()), "EA: missing MergeMem node in the worklist");
        }
      } else {
        uint op = use->Opcode();
        if (!(op == Op_CmpP || op == Op_Conv2B ||
              op == Op_CastP2X || op == Op_StoreCM ||
              op == Op_FastLock || op == Op_AryEq || op == Op_StrComp ||
              op == Op_StrEquals || op == Op_StrIndexOf)) {
          n->dump();
          use->dump();
          assert(false, "EA: missing allocation reference path");
        }
#endif
      }
    }

  }
  // New alias types were created in split_AddP().
  uint new_index_end = (uint) _compile->num_alias_types();

  //  Phase 2:  Process MemNode's from memnode_worklist. compute new address type and
  //            compute new values for Memory inputs  (the Memory inputs are not
  //            actually updated until phase 4.)
  if (memnode_worklist.length() == 0)
    return;  // nothing to do

  while (memnode_worklist.length() != 0) {
    Node *n = memnode_worklist.pop();
    if (visited.test_set(n->_idx))
      continue;
    if (n->is_Phi() || n->is_ClearArray()) {
      // we don't need to do anything, but the users must be pushed
    } else if (n->is_MemBar()) { // Initialize, MemBar nodes
      // we don't need to do anything, but the users must be pushed
      n = n->as_MemBar()->proj_out(TypeFunc::Memory);
      if (n == NULL)
        continue;
    } else {
      assert(n->is_Mem(), "memory node required.");
      Node *addr = n->in(MemNode::Address);
      const Type *addr_t = igvn->type(addr);
      if (addr_t == Type::TOP)
        continue;
      assert (addr_t->isa_ptr() != NULL, "pointer type required.");
      int alias_idx = _compile->get_alias_index(addr_t->is_ptr());
      assert ((uint)alias_idx < new_index_end, "wrong alias index");
      Node *mem = find_inst_mem(n->in(MemNode::Memory), alias_idx, orig_phis, igvn);
      if (_compile->failing()) {
        return;
      }
      if (mem != n->in(MemNode::Memory)) {
        // We delay the memory edge update since we need old one in
        // MergeMem code below when instances memory slices are separated.
        debug_only(Node* pn = ptnode_adr(n->_idx)->_node;)
        assert(pn == NULL || pn == n, "wrong node");
        set_map(n->_idx, mem);
        ptnode_adr(n->_idx)->_node = n;
      }
      if (n->is_Load()) {
        continue;  // don't push users
      } else if (n->is_LoadStore()) {
        // get the memory projection
        for (DUIterator_Fast imax, i = n->fast_outs(imax); i < imax; i++) {
          Node *use = n->fast_out(i);
          if (use->Opcode() == Op_SCMemProj) {
            n = use;
            break;
          }
        }
        assert(n->Opcode() == Op_SCMemProj, "memory projection required");
      }
    }
    // push user on appropriate worklist
    for (DUIterator_Fast imax, i = n->fast_outs(imax); i < imax; i++) {
      Node *use = n->fast_out(i);
      if (use->is_Phi() || use->is_ClearArray()) {
        memnode_worklist.append_if_missing(use);
      } else if(use->is_Mem() && use->in(MemNode::Memory) == n) {
        if (use->Opcode() == Op_StoreCM) // Ignore cardmark stores
          continue;
        memnode_worklist.append_if_missing(use);
      } else if (use->is_MemBar()) {
        memnode_worklist.append_if_missing(use);
#ifdef ASSERT
      } else if(use->is_Mem()) {
        assert(use->in(MemNode::Memory) != n, "EA: missing memory path");
      } else if (use->is_MergeMem()) {
        assert(_mergemem_worklist.contains(use->as_MergeMem()), "EA: missing MergeMem node in the worklist");
      } else {
        uint op = use->Opcode();
        if (!(op == Op_StoreCM ||
              (op == Op_CallLeaf && use->as_CallLeaf()->_name != NULL &&
               strcmp(use->as_CallLeaf()->_name, "g1_wb_pre") == 0) ||
              op == Op_AryEq || op == Op_StrComp ||
              op == Op_StrEquals || op == Op_StrIndexOf)) {
          n->dump();
          use->dump();
          assert(false, "EA: missing memory path");
        }
#endif
      }
    }
  }

  //  Phase 3:  Process MergeMem nodes from mergemem_worklist.
  //            Walk each memory slice moving the first node encountered of each
  //            instance type to the the input corresponding to its alias index.
  uint length = _mergemem_worklist.length();
  for( uint next = 0; next < length; ++next ) {
    MergeMemNode* nmm = _mergemem_worklist.at(next);
    assert(!visited.test_set(nmm->_idx), "should not be visited before");
    // Note: we don't want to use MergeMemStream here because we only want to
    // scan inputs which exist at the start, not ones we add during processing.
    // Note 2: MergeMem may already contains instance memory slices added
    // during find_inst_mem() call when memory nodes were processed above.
    igvn->hash_delete(nmm);
    uint nslices = nmm->req();
    for (uint i = Compile::AliasIdxRaw+1; i < nslices; i++) {
      Node* mem = nmm->in(i);
      Node* cur = NULL;
      if (mem == NULL || mem->is_top())
        continue;
      // First, update mergemem by moving memory nodes to corresponding slices
      // if their type became more precise since this mergemem was created.
      while (mem->is_Mem()) {
        const Type *at = igvn->type(mem->in(MemNode::Address));
        if (at != Type::TOP) {
          assert (at->isa_ptr() != NULL, "pointer type required.");
          uint idx = (uint)_compile->get_alias_index(at->is_ptr());
          if (idx == i) {
            if (cur == NULL)
              cur = mem;
          } else {
            if (idx >= nmm->req() || nmm->is_empty_memory(nmm->in(idx))) {
              nmm->set_memory_at(idx, mem);
            }
          }
        }
        mem = mem->in(MemNode::Memory);
      }
      nmm->set_memory_at(i, (cur != NULL) ? cur : mem);
      // Find any instance of the current type if we haven't encountered
      // already a memory slice of the instance along the memory chain.
      for (uint ni = new_index_start; ni < new_index_end; ni++) {
        if((uint)_compile->get_general_index(ni) == i) {
          Node *m = (ni >= nmm->req()) ? nmm->empty_memory() : nmm->in(ni);
          if (nmm->is_empty_memory(m)) {
            Node* result = find_inst_mem(mem, ni, orig_phis, igvn);
            if (_compile->failing()) {
              return;
            }
            nmm->set_memory_at(ni, result);
          }
        }
      }
    }
    // Find the rest of instances values
    for (uint ni = new_index_start; ni < new_index_end; ni++) {
      const TypeOopPtr *tinst = _compile->get_adr_type(ni)->isa_oopptr();
      Node* result = step_through_mergemem(nmm, ni, tinst);
      if (result == nmm->base_memory()) {
        // Didn't find instance memory, search through general slice recursively.
        result = nmm->memory_at(_compile->get_general_index(ni));
        result = find_inst_mem(result, ni, orig_phis, igvn);
        if (_compile->failing()) {
          return;
        }
        nmm->set_memory_at(ni, result);
      }
    }
    igvn->hash_insert(nmm);
    record_for_optimizer(nmm);
  }

  //  Phase 4:  Update the inputs of non-instance memory Phis and
  //            the Memory input of memnodes
  // First update the inputs of any non-instance Phi's from
  // which we split out an instance Phi.  Note we don't have
  // to recursively process Phi's encounted on the input memory
  // chains as is done in split_memory_phi() since they  will
  // also be processed here.
  for (int j = 0; j < orig_phis.length(); j++) {
    PhiNode *phi = orig_phis.at(j);
    int alias_idx = _compile->get_alias_index(phi->adr_type());
    igvn->hash_delete(phi);
    for (uint i = 1; i < phi->req(); i++) {
      Node *mem = phi->in(i);
      Node *new_mem = find_inst_mem(mem, alias_idx, orig_phis, igvn);
      if (_compile->failing()) {
        return;
      }
      if (mem != new_mem) {
        phi->set_req(i, new_mem);
      }
    }
    igvn->hash_insert(phi);
    record_for_optimizer(phi);
  }

  // Update the memory inputs of MemNodes with the value we computed
  // in Phase 2 and move stores memory users to corresponding memory slices.
#ifdef ASSERT
  visited.Clear();
  Node_Stack old_mems(arena, _compile->unique() >> 2);
#endif
  for (uint i = 0; i < nodes_size(); i++) {
    Node *nmem = get_map(i);
    if (nmem != NULL) {
      Node *n = ptnode_adr(i)->_node;
      assert(n != NULL, "sanity");
      if (n->is_Mem()) {
#ifdef ASSERT
        Node* old_mem = n->in(MemNode::Memory);
        if (!visited.test_set(old_mem->_idx)) {
          old_mems.push(old_mem, old_mem->outcnt());
        }
#endif
        assert(n->in(MemNode::Memory) != nmem, "sanity");
        if (!n->is_Load()) {
          // Move memory users of a store first.
          move_inst_mem(n, orig_phis, igvn);
        }
        // Now update memory input
        igvn->hash_delete(n);
        n->set_req(MemNode::Memory, nmem);
        igvn->hash_insert(n);
        record_for_optimizer(n);
      } else {
        assert(n->is_Allocate() || n->is_CheckCastPP() ||
               n->is_AddP() || n->is_Phi(), "unknown node used for set_map()");
      }
    }
  }
#ifdef ASSERT
  // Verify that memory was split correctly
  while (old_mems.is_nonempty()) {
    Node* old_mem = old_mems.node();
    uint  old_cnt = old_mems.index();
    old_mems.pop();
    assert(old_cnt = old_mem->outcnt(), "old mem could be lost");
  }
#endif
}

bool ConnectionGraph::has_candidates(Compile *C) {
  // EA brings benefits only when the code has allocations and/or locks which
  // are represented by ideal Macro nodes.
  int cnt = C->macro_count();
  for( int i=0; i < cnt; i++ ) {
    Node *n = C->macro_node(i);
    if ( n->is_Allocate() )
      return true;
    if( n->is_Lock() ) {
      Node* obj = n->as_Lock()->obj_node()->uncast();
      if( !(obj->is_Parm() || obj->is_Con()) )
        return true;
    }
  }
  return false;
}

void ConnectionGraph::do_analysis(Compile *C, PhaseIterGVN *igvn) {
  // Add ConP#NULL and ConN#NULL nodes before ConnectionGraph construction
  // to create space for them in ConnectionGraph::_nodes[].
  Node* oop_null = igvn->zerocon(T_OBJECT);
  Node* noop_null = igvn->zerocon(T_NARROWOOP);

  ConnectionGraph* congraph = new(C->comp_arena()) ConnectionGraph(C, igvn);
  // Perform escape analysis
  if (congraph->compute_escape()) {
    // There are non escaping objects.
    C->set_congraph(congraph);
  }

  // Cleanup.
  if (oop_null->outcnt() == 0)
    igvn->hash_delete(oop_null);
  if (noop_null->outcnt() == 0)
    igvn->hash_delete(noop_null);
}

bool ConnectionGraph::compute_escape() {
  Compile* C = _compile;

  // 1. Populate Connection Graph (CG) with Ideal nodes.

  Unique_Node_List worklist_init;
  worklist_init.map(C->unique(), NULL);  // preallocate space

  // Initialize worklist
  if (C->root() != NULL) {
    worklist_init.push(C->root());
  }

  GrowableArray<int> cg_worklist;
  PhaseGVN* igvn = _igvn;
  bool has_allocations = false;

  // Push all useful nodes onto CG list and set their type.
  for( uint next = 0; next < worklist_init.size(); ++next ) {
    Node* n = worklist_init.at(next);
    record_for_escape_analysis(n, igvn);
    // Only allocations and java static calls results are checked
    // for an escape status. See process_call_result() below.
    if (n->is_Allocate() || n->is_CallStaticJava() &&
        ptnode_adr(n->_idx)->node_type() == PointsToNode::JavaObject) {
      has_allocations = true;
    }
    if(n->is_AddP()) {
      // Collect address nodes. Use them during stage 3 below
      // to build initial connection graph field edges.
      cg_worklist.append(n->_idx);
    } else if (n->is_MergeMem()) {
      // Collect all MergeMem nodes to add memory slices for
      // scalar replaceable objects in split_unique_types().
      _mergemem_worklist.append(n->as_MergeMem());
    }
    for (DUIterator_Fast imax, i = n->fast_outs(imax); i < imax; i++) {
      Node* m = n->fast_out(i);   // Get user
      worklist_init.push(m);
    }
  }

  if (!has_allocations) {
    _collecting = false;
    return false; // Nothing to do.
  }

  // 2. First pass to create simple CG edges (doesn't require to walk CG).
  uint delayed_size = _delayed_worklist.size();
  for( uint next = 0; next < delayed_size; ++next ) {
    Node* n = _delayed_worklist.at(next);
    build_connection_graph(n, igvn);
  }

  // 3. Pass to create initial fields edges (JavaObject -F-> AddP)
  //    to reduce number of iterations during stage 4 below.
  uint cg_length = cg_worklist.length();
  for( uint next = 0; next < cg_length; ++next ) {
    int ni = cg_worklist.at(next);
    Node* n = ptnode_adr(ni)->_node;
    Node* base = get_addp_base(n);
    if (base->is_Proj())
      base = base->in(0);
    PointsToNode::NodeType nt = ptnode_adr(base->_idx)->node_type();
    if (nt == PointsToNode::JavaObject) {
      build_connection_graph(n, igvn);
    }
  }

  cg_worklist.clear();
  cg_worklist.append(_phantom_object);
  GrowableArray<uint>  worklist;

  // 4. Build Connection Graph which need
  //    to walk the connection graph.
  _progress = false;
  for (uint ni = 0; ni < nodes_size(); ni++) {
    PointsToNode* ptn = ptnode_adr(ni);
    Node *n = ptn->_node;
    if (n != NULL) { // Call, AddP, LoadP, StoreP
      build_connection_graph(n, igvn);
      if (ptn->node_type() != PointsToNode::UnknownType)
        cg_worklist.append(n->_idx); // Collect CG nodes
      if (!_processed.test(n->_idx))
        worklist.append(n->_idx); // Collect C/A/L/S nodes
    }
  }

  // After IGVN user nodes may have smaller _idx than
  // their inputs so they will be processed first in
  // previous loop. Because of that not all Graph
  // edges will be created. Walk over interesting
  // nodes again until no new edges are created.
  //
  // Normally only 1-3 passes needed to build
  // Connection Graph depending on graph complexity.
  // Set limit to 10 to catch situation when something
  // did go wrong and recompile the method without EA.

#define CG_BUILD_ITER_LIMIT 10

  uint length = worklist.length();
  int iterations = 0;
  while(_progress && (iterations++ < CG_BUILD_ITER_LIMIT)) {
    _progress = false;
    for( uint next = 0; next < length; ++next ) {
      int ni = worklist.at(next);
      PointsToNode* ptn = ptnode_adr(ni);
      Node* n = ptn->_node;
      assert(n != NULL, "should be known node");
      build_connection_graph(n, igvn);
    }
  }
  if (iterations >= CG_BUILD_ITER_LIMIT) {
    assert(iterations < CG_BUILD_ITER_LIMIT,
           err_msg("infinite EA connection graph build with %d nodes and worklist size %d",
           nodes_size(), length));
    // Possible infinite build_connection_graph loop,
    // retry compilation without escape analysis.
    C->record_failure(C2Compiler::retry_no_escape_analysis());
    _collecting = false;
    return false;
  }
#undef CG_BUILD_ITER_LIMIT

  Arena* arena = Thread::current()->resource_area();
  VectorSet ptset(arena);
  VectorSet visited(arena);
  worklist.clear();

  // 5. Remove deferred edges from the graph and adjust
  //    escape state of nonescaping objects.
  cg_length = cg_worklist.length();
  for( uint next = 0; next < cg_length; ++next ) {
    int ni = cg_worklist.at(next);
    PointsToNode* ptn = ptnode_adr(ni);
    PointsToNode::NodeType nt = ptn->node_type();
    if (nt == PointsToNode::LocalVar || nt == PointsToNode::Field) {
      remove_deferred(ni, &worklist, &visited);
      Node *n = ptn->_node;
      if (n->is_AddP()) {
        // Search for objects which are not scalar replaceable
        // and adjust their escape state.
        verify_escape_state(ni, ptset, igvn);
      }
    }
  }

  // 6. Propagate escape states.
  worklist.clear();
  bool has_non_escaping_obj = false;

  // push all GlobalEscape nodes on the worklist
  for( uint next = 0; next < cg_length; ++next ) {
    int nk = cg_worklist.at(next);
    if (ptnode_adr(nk)->escape_state() == PointsToNode::GlobalEscape)
      worklist.push(nk);
  }
  // mark all nodes reachable from GlobalEscape nodes
  while(worklist.length() > 0) {
    PointsToNode* ptn = ptnode_adr(worklist.pop());
    uint e_cnt = ptn->edge_count();
    for (uint ei = 0; ei < e_cnt; ei++) {
      uint npi = ptn->edge_target(ei);
      PointsToNode *np = ptnode_adr(npi);
      if (np->escape_state() < PointsToNode::GlobalEscape) {
        np->set_escape_state(PointsToNode::GlobalEscape);
        worklist.push(npi);
      }
    }
  }

  // push all ArgEscape nodes on the worklist
  for( uint next = 0; next < cg_length; ++next ) {
    int nk = cg_worklist.at(next);
    if (ptnode_adr(nk)->escape_state() == PointsToNode::ArgEscape)
      worklist.push(nk);
  }
  // mark all nodes reachable from ArgEscape nodes
  while(worklist.length() > 0) {
    PointsToNode* ptn = ptnode_adr(worklist.pop());
    if (ptn->node_type() == PointsToNode::JavaObject)
      has_non_escaping_obj = true; // Non GlobalEscape
    uint e_cnt = ptn->edge_count();
    for (uint ei = 0; ei < e_cnt; ei++) {
      uint npi = ptn->edge_target(ei);
      PointsToNode *np = ptnode_adr(npi);
      if (np->escape_state() < PointsToNode::ArgEscape) {
        np->set_escape_state(PointsToNode::ArgEscape);
        worklist.push(npi);
      }
    }
  }

  GrowableArray<Node*> alloc_worklist;

  // push all NoEscape nodes on the worklist
  for( uint next = 0; next < cg_length; ++next ) {
    int nk = cg_worklist.at(next);
    if (ptnode_adr(nk)->escape_state() == PointsToNode::NoEscape)
      worklist.push(nk);
  }
  // mark all nodes reachable from NoEscape nodes
  while(worklist.length() > 0) {
    PointsToNode* ptn = ptnode_adr(worklist.pop());
    if (ptn->node_type() == PointsToNode::JavaObject)
      has_non_escaping_obj = true; // Non GlobalEscape
    Node* n = ptn->_node;
    if (n->is_Allocate() && ptn->_scalar_replaceable ) {
      // Push scalar replaceable allocations on alloc_worklist
      // for processing in split_unique_types().
      alloc_worklist.append(n);
    }
    uint e_cnt = ptn->edge_count();
    for (uint ei = 0; ei < e_cnt; ei++) {
      uint npi = ptn->edge_target(ei);
      PointsToNode *np = ptnode_adr(npi);
      if (np->escape_state() < PointsToNode::NoEscape) {
        np->set_escape_state(PointsToNode::NoEscape);
        worklist.push(npi);
      }
    }
  }

  _collecting = false;
  assert(C->unique() == nodes_size(), "there should be no new ideal nodes during ConnectionGraph build");

#ifndef PRODUCT
  if (PrintEscapeAnalysis) {
    dump(); // Dump ConnectionGraph
  }
#endif

  bool has_scalar_replaceable_candidates = alloc_worklist.length() > 0;
  if ( has_scalar_replaceable_candidates &&
       C->AliasLevel() >= 3 && EliminateAllocations ) {

    // Now use the escape information to create unique types for
    // scalar replaceable objects.
    split_unique_types(alloc_worklist);

    if (C->failing())  return false;

    C->print_method("After Escape Analysis", 2);

#ifdef ASSERT
  } else if (Verbose && (PrintEscapeAnalysis || PrintEliminateAllocations)) {
    tty->print("=== No allocations eliminated for ");
    C->method()->print_short_name();
    if(!EliminateAllocations) {
      tty->print(" since EliminateAllocations is off ===");
    } else if(!has_scalar_replaceable_candidates) {
      tty->print(" since there are no scalar replaceable candidates ===");
    } else if(C->AliasLevel() < 3) {
      tty->print(" since AliasLevel < 3 ===");
    }
    tty->cr();
#endif
  }
  return has_non_escaping_obj;
}

// Search for objects which are not scalar replaceable.
void ConnectionGraph::verify_escape_state(int nidx, VectorSet& ptset, PhaseTransform* phase) {
  PointsToNode* ptn = ptnode_adr(nidx);
  Node* n = ptn->_node;
  assert(n->is_AddP(), "Should be called for AddP nodes only");
  // Search for objects which are not scalar replaceable.
  // Mark their escape state as ArgEscape to propagate the state
  // to referenced objects.
  // Note: currently there are no difference in compiler optimizations
  // for ArgEscape objects and NoEscape objects which are not
  // scalar replaceable.

  Compile* C = _compile;

  int offset = ptn->offset();
  Node* base = get_addp_base(n);
  ptset.Clear();
  PointsTo(ptset, base);
  int ptset_size = ptset.Size();

  // Check if a oop field's initializing value is recorded and add
  // a corresponding NULL field's value if it is not recorded.
  // Connection Graph does not record a default initialization by NULL
  // captured by Initialize node.
  //
  // Note: it will disable scalar replacement in some cases:
  //
  //    Point p[] = new Point[1];
  //    p[0] = new Point(); // Will be not scalar replaced
  //
  // but it will save us from incorrect optimizations in next cases:
  //
  //    Point p[] = new Point[1];
  //    if ( x ) p[0] = new Point(); // Will be not scalar replaced
  //
  // Do a simple control flow analysis to distinguish above cases.
  //
  if (offset != Type::OffsetBot && ptset_size == 1) {
    uint elem = ptset.getelem(); // Allocation node's index
    // It does not matter if it is not Allocation node since
    // only non-escaping allocations are scalar replaced.
    if (ptnode_adr(elem)->_node->is_Allocate() &&
        ptnode_adr(elem)->escape_state() == PointsToNode::NoEscape) {
      AllocateNode* alloc = ptnode_adr(elem)->_node->as_Allocate();
      InitializeNode* ini = alloc->initialization();

      // Check only oop fields.
      const Type* adr_type = n->as_AddP()->bottom_type();
      BasicType basic_field_type = T_INT;
      if (adr_type->isa_instptr()) {
        ciField* field = C->alias_type(adr_type->isa_instptr())->field();
        if (field != NULL) {
          basic_field_type = field->layout_type();
        } else {
          // Ignore non field load (for example, klass load)
        }
      } else if (adr_type->isa_aryptr()) {
        const Type* elemtype = adr_type->isa_aryptr()->elem();
        basic_field_type = elemtype->array_element_basic_type();
      } else {
        // Raw pointers are used for initializing stores so skip it.
        assert(adr_type->isa_rawptr() && base->is_Proj() &&
               (base->in(0) == alloc),"unexpected pointer type");
      }
      if (basic_field_type == T_OBJECT ||
          basic_field_type == T_NARROWOOP ||
          basic_field_type == T_ARRAY) {
        Node* value = NULL;
        if (ini != NULL) {
          BasicType ft = UseCompressedOops ? T_NARROWOOP : T_OBJECT;
          Node* store = ini->find_captured_store(offset, type2aelembytes(ft), phase);
          if (store != NULL && store->is_Store()) {
            value = store->in(MemNode::ValueIn);
          } else if (ptn->edge_count() > 0) { // Are there oop stores?
            // Check for a store which follows allocation without branches.
            // For example, a volatile field store is not collected
            // by Initialize node. TODO: it would be nice to use idom() here.
            for (DUIterator_Fast imax, i = n->fast_outs(imax); i < imax; i++) {
              store = n->fast_out(i);
              if (store->is_Store() && store->in(0) != NULL) {
                Node* ctrl = store->in(0);
                while(!(ctrl == ini || ctrl == alloc || ctrl == NULL ||
                        ctrl == C->root() || ctrl == C->top() || ctrl->is_Region() ||
                        ctrl->is_IfTrue() || ctrl->is_IfFalse())) {
                   ctrl = ctrl->in(0);
                }
                if (ctrl == ini || ctrl == alloc) {
                  value = store->in(MemNode::ValueIn);
                  break;
                }
              }
            }
          }
        }
        if (value == NULL || value != ptnode_adr(value->_idx)->_node) {
          // A field's initializing value was not recorded. Add NULL.
          uint null_idx = UseCompressedOops ? _noop_null : _oop_null;
          add_pointsto_edge(nidx, null_idx);
        }
      }
    }
  }

  // An object is not scalar replaceable if the field which may point
  // to it has unknown offset (unknown element of an array of objects).
  //
  if (offset == Type::OffsetBot) {
    uint e_cnt = ptn->edge_count();
    for (uint ei = 0; ei < e_cnt; ei++) {
      uint npi = ptn->edge_target(ei);
      set_escape_state(npi, PointsToNode::ArgEscape);
      ptnode_adr(npi)->_scalar_replaceable = false;
    }
  }

  // Currently an object is not scalar replaceable if a LoadStore node
  // access its field since the field value is unknown after it.
  //
  bool has_LoadStore = false;
  for (DUIterator_Fast imax, i = n->fast_outs(imax); i < imax; i++) {
    Node *use = n->fast_out(i);
    if (use->is_LoadStore()) {
      has_LoadStore = true;
      break;
    }
  }
  // An object is not scalar replaceable if the address points
  // to unknown field (unknown element for arrays, offset is OffsetBot).
  //
  // Or the address may point to more then one object. This may produce
  // the false positive result (set scalar_replaceable to false)
  // since the flow-insensitive escape analysis can't separate
  // the case when stores overwrite the field's value from the case
  // when stores happened on different control branches.
  //
  if (ptset_size > 1 || ptset_size != 0 &&
      (has_LoadStore || offset == Type::OffsetBot)) {
    for( VectorSetI j(&ptset); j.test(); ++j ) {
      set_escape_state(j.elem, PointsToNode::ArgEscape);
      ptnode_adr(j.elem)->_scalar_replaceable = false;
    }
  }
}

void ConnectionGraph::process_call_arguments(CallNode *call, PhaseTransform *phase) {

    switch (call->Opcode()) {
#ifdef ASSERT
    case Op_Allocate:
    case Op_AllocateArray:
    case Op_Lock:
    case Op_Unlock:
      assert(false, "should be done already");
      break;
#endif
    case Op_CallLeaf:
    case Op_CallLeafNoFP:
    {
      // Stub calls, objects do not escape but they are not scale replaceable.
      // Adjust escape state for outgoing arguments.
      const TypeTuple * d = call->tf()->domain();
      VectorSet ptset(Thread::current()->resource_area());
      for (uint i = TypeFunc::Parms; i < d->cnt(); i++) {
        const Type* at = d->field_at(i);
        Node *arg = call->in(i)->uncast();
        const Type *aat = phase->type(arg);
        if (!arg->is_top() && at->isa_ptr() && aat->isa_ptr() &&
            ptnode_adr(arg->_idx)->escape_state() < PointsToNode::ArgEscape) {

          assert(aat == Type::TOP || aat == TypePtr::NULL_PTR ||
                 aat->isa_ptr() != NULL, "expecting an Ptr");
#ifdef ASSERT
          if (!(call->Opcode() == Op_CallLeafNoFP &&
                call->as_CallLeaf()->_name != NULL &&
                (strstr(call->as_CallLeaf()->_name, "arraycopy")  != 0) ||
                call->as_CallLeaf()->_name != NULL &&
                (strcmp(call->as_CallLeaf()->_name, "g1_wb_pre")  == 0 ||
                 strcmp(call->as_CallLeaf()->_name, "g1_wb_post") == 0 ))
          ) {
            call->dump();
            assert(false, "EA: unexpected CallLeaf");
          }
#endif
          set_escape_state(arg->_idx, PointsToNode::ArgEscape);
          if (arg->is_AddP()) {
            //
            // The inline_native_clone() case when the arraycopy stub is called
            // after the allocation before Initialize and CheckCastPP nodes.
            //
            // Set AddP's base (Allocate) as not scalar replaceable since
            // pointer to the base (with offset) is passed as argument.
            //
            arg = get_addp_base(arg);
          }
          ptset.Clear();
          PointsTo(ptset, arg);
          for( VectorSetI j(&ptset); j.test(); ++j ) {
            uint pt = j.elem;
            set_escape_state(pt, PointsToNode::ArgEscape);
          }
        }
      }
      break;
    }

    case Op_CallStaticJava:
    // For a static call, we know exactly what method is being called.
    // Use bytecode estimator to record the call's escape affects
    {
      ciMethod *meth = call->as_CallJava()->method();
      BCEscapeAnalyzer *call_analyzer = (meth !=NULL) ? meth->get_bcea() : NULL;
      // fall-through if not a Java method or no analyzer information
      if (call_analyzer != NULL) {
        const TypeTuple * d = call->tf()->domain();
        VectorSet ptset(Thread::current()->resource_area());
        bool copy_dependencies = false;
        for (uint i = TypeFunc::Parms; i < d->cnt(); i++) {
          const Type* at = d->field_at(i);
          int k = i - TypeFunc::Parms;
          Node *arg = call->in(i)->uncast();

          if (at->isa_oopptr() != NULL &&
              ptnode_adr(arg->_idx)->escape_state() < PointsToNode::GlobalEscape) {

            bool global_escapes = false;
            bool fields_escapes = false;
            if (!call_analyzer->is_arg_stack(k)) {
              // The argument global escapes, mark everything it could point to
              set_escape_state(arg->_idx, PointsToNode::GlobalEscape);
              global_escapes = true;
            } else {
              if (!call_analyzer->is_arg_local(k)) {
                // The argument itself doesn't escape, but any fields might
                fields_escapes = true;
              }
              set_escape_state(arg->_idx, PointsToNode::ArgEscape);
              copy_dependencies = true;
            }

            ptset.Clear();
            PointsTo(ptset, arg);
            for( VectorSetI j(&ptset); j.test(); ++j ) {
              uint pt = j.elem;
              if (global_escapes) {
                //The argument global escapes, mark everything it could point to
                set_escape_state(pt, PointsToNode::GlobalEscape);
              } else {
                if (fields_escapes) {
                  // The argument itself doesn't escape, but any fields might
                  add_edge_from_fields(pt, _phantom_object, Type::OffsetBot);
                }
                set_escape_state(pt, PointsToNode::ArgEscape);
              }
            }
          }
        }
        if (copy_dependencies)
          call_analyzer->copy_dependencies(_compile->dependencies());
        break;
      }
    }

    default:
    // Fall-through here if not a Java method or no analyzer information
    // or some other type of call, assume the worst case: all arguments
    // globally escape.
    {
      // adjust escape state for  outgoing arguments
      const TypeTuple * d = call->tf()->domain();
      VectorSet ptset(Thread::current()->resource_area());
      for (uint i = TypeFunc::Parms; i < d->cnt(); i++) {
        const Type* at = d->field_at(i);
        if (at->isa_oopptr() != NULL) {
          Node *arg = call->in(i)->uncast();
          set_escape_state(arg->_idx, PointsToNode::GlobalEscape);
          ptset.Clear();
          PointsTo(ptset, arg);
          for( VectorSetI j(&ptset); j.test(); ++j ) {
            uint pt = j.elem;
            set_escape_state(pt, PointsToNode::GlobalEscape);
          }
        }
      }
    }
  }
}
void ConnectionGraph::process_call_result(ProjNode *resproj, PhaseTransform *phase) {
  CallNode   *call = resproj->in(0)->as_Call();
  uint    call_idx = call->_idx;
  uint resproj_idx = resproj->_idx;

  switch (call->Opcode()) {
    case Op_Allocate:
    {
      Node *k = call->in(AllocateNode::KlassNode);
      const TypeKlassPtr *kt = k->bottom_type()->isa_klassptr();
      assert(kt != NULL, "TypeKlassPtr  required.");
      ciKlass* cik = kt->klass();

      PointsToNode::EscapeState es;
      uint edge_to;
      if (cik->is_subclass_of(_compile->env()->Thread_klass()) ||
         !cik->is_instance_klass() || // StressReflectiveCode
          cik->as_instance_klass()->has_finalizer()) {
        es = PointsToNode::GlobalEscape;
        edge_to = _phantom_object; // Could not be worse
      } else {
        es = PointsToNode::NoEscape;
        edge_to = call_idx;
      }
      set_escape_state(call_idx, es);
      add_pointsto_edge(resproj_idx, edge_to);
      _processed.set(resproj_idx);
      break;
    }

    case Op_AllocateArray:
    {

      Node *k = call->in(AllocateNode::KlassNode);
      const TypeKlassPtr *kt = k->bottom_type()->isa_klassptr();
      assert(kt != NULL, "TypeKlassPtr  required.");
      ciKlass* cik = kt->klass();

      PointsToNode::EscapeState es;
      uint edge_to;
      if (!cik->is_array_klass()) { // StressReflectiveCode
        es = PointsToNode::GlobalEscape;
        edge_to = _phantom_object;
      } else {
        es = PointsToNode::NoEscape;
        edge_to = call_idx;
        int length = call->in(AllocateNode::ALength)->find_int_con(-1);
        if (length < 0 || length > EliminateAllocationArraySizeLimit) {
          // Not scalar replaceable if the length is not constant or too big.
          ptnode_adr(call_idx)->_scalar_replaceable = false;
        }
      }
      set_escape_state(call_idx, es);
      add_pointsto_edge(resproj_idx, edge_to);
      _processed.set(resproj_idx);
      break;
    }

    case Op_CallStaticJava:
    // For a static call, we know exactly what method is being called.
    // Use bytecode estimator to record whether the call's return value escapes
    {
      bool done = true;
      const TypeTuple *r = call->tf()->range();
      const Type* ret_type = NULL;

      if (r->cnt() > TypeFunc::Parms)
        ret_type = r->field_at(TypeFunc::Parms);

      // Note:  we use isa_ptr() instead of isa_oopptr()  here because the
      //        _multianewarray functions return a TypeRawPtr.
      if (ret_type == NULL || ret_type->isa_ptr() == NULL) {
        _processed.set(resproj_idx);
        break;  // doesn't return a pointer type
      }
      ciMethod *meth = call->as_CallJava()->method();
      const TypeTuple * d = call->tf()->domain();
      if (meth == NULL) {
        // not a Java method, assume global escape
        set_escape_state(call_idx, PointsToNode::GlobalEscape);
        add_pointsto_edge(resproj_idx, _phantom_object);
      } else {
        BCEscapeAnalyzer *call_analyzer = meth->get_bcea();
        bool copy_dependencies = false;

        if (call_analyzer->is_return_allocated()) {
          // Returns a newly allocated unescaped object, simply
          // update dependency information.
          // Mark it as NoEscape so that objects referenced by
          // it's fields will be marked as NoEscape at least.
          set_escape_state(call_idx, PointsToNode::NoEscape);
          add_pointsto_edge(resproj_idx, call_idx);
          copy_dependencies = true;
        } else if (call_analyzer->is_return_local()) {
          // determine whether any arguments are returned
          set_escape_state(call_idx, PointsToNode::NoEscape);
          bool ret_arg = false;
          for (uint i = TypeFunc::Parms; i < d->cnt(); i++) {
            const Type* at = d->field_at(i);

            if (at->isa_oopptr() != NULL) {
              Node *arg = call->in(i)->uncast();

              if (call_analyzer->is_arg_returned(i - TypeFunc::Parms)) {
                ret_arg = true;
                PointsToNode *arg_esp = ptnode_adr(arg->_idx);
                if (arg_esp->node_type() == PointsToNode::UnknownType)
                  done = false;
                else if (arg_esp->node_type() == PointsToNode::JavaObject)
                  add_pointsto_edge(resproj_idx, arg->_idx);
                else
                  add_deferred_edge(resproj_idx, arg->_idx);
                arg_esp->_hidden_alias = true;
              }
            }
          }
          if (done && !ret_arg) {
            // Returns unknown object.
            set_escape_state(call_idx, PointsToNode::GlobalEscape);
            add_pointsto_edge(resproj_idx, _phantom_object);
          }
          copy_dependencies = true;
        } else {
          set_escape_state(call_idx, PointsToNode::GlobalEscape);
          add_pointsto_edge(resproj_idx, _phantom_object);
          for (uint i = TypeFunc::Parms; i < d->cnt(); i++) {
            const Type* at = d->field_at(i);
            if (at->isa_oopptr() != NULL) {
              Node *arg = call->in(i)->uncast();
              PointsToNode *arg_esp = ptnode_adr(arg->_idx);
              arg_esp->_hidden_alias = true;
            }
          }
        }
        if (copy_dependencies)
          call_analyzer->copy_dependencies(_compile->dependencies());
      }
      if (done)
        _processed.set(resproj_idx);
      break;
    }

    default:
    // Some other type of call, assume the worst case that the
    // returned value, if any, globally escapes.
    {
      const TypeTuple *r = call->tf()->range();
      if (r->cnt() > TypeFunc::Parms) {
        const Type* ret_type = r->field_at(TypeFunc::Parms);

        // Note:  we use isa_ptr() instead of isa_oopptr()  here because the
        //        _multianewarray functions return a TypeRawPtr.
        if (ret_type->isa_ptr() != NULL) {
          set_escape_state(call_idx, PointsToNode::GlobalEscape);
          add_pointsto_edge(resproj_idx, _phantom_object);
        }
      }
      _processed.set(resproj_idx);
    }
  }
}

// Populate Connection Graph with Ideal nodes and create simple
// connection graph edges (do not need to check the node_type of inputs
// or to call PointsTo() to walk the connection graph).
void ConnectionGraph::record_for_escape_analysis(Node *n, PhaseTransform *phase) {
  if (_processed.test(n->_idx))
    return; // No need to redefine node's state.

  if (n->is_Call()) {
    // Arguments to allocation and locking don't escape.
    if (n->is_Allocate()) {
      add_node(n, PointsToNode::JavaObject, PointsToNode::UnknownEscape, true);
      record_for_optimizer(n);
    } else if (n->is_Lock() || n->is_Unlock()) {
      // Put Lock and Unlock nodes on IGVN worklist to process them during
      // the first IGVN optimization when escape information is still available.
      record_for_optimizer(n);
      _processed.set(n->_idx);
    } else {
      // Don't mark as processed since call's arguments have to be processed.
      PointsToNode::NodeType nt = PointsToNode::UnknownType;
      PointsToNode::EscapeState es = PointsToNode::UnknownEscape;

      // Check if a call returns an object.
      const TypeTuple *r = n->as_Call()->tf()->range();
      if (r->cnt() > TypeFunc::Parms &&
          r->field_at(TypeFunc::Parms)->isa_ptr() &&
          n->as_Call()->proj_out(TypeFunc::Parms) != NULL) {
        nt = PointsToNode::JavaObject;
        if (!n->is_CallStaticJava()) {
          // Since the called mathod is statically unknown assume
          // the worst case that the returned value globally escapes.
          es = PointsToNode::GlobalEscape;
        }
      }
      add_node(n, nt, es, false);
    }
    return;
  }

  // Using isa_ptr() instead of isa_oopptr() for LoadP and Phi because
  // ThreadLocal has RawPrt type.
  switch (n->Opcode()) {
    case Op_AddP:
    {
      add_node(n, PointsToNode::Field, PointsToNode::UnknownEscape, false);
      break;
    }
    case Op_CastX2P:
    { // "Unsafe" memory access.
      add_node(n, PointsToNode::JavaObject, PointsToNode::GlobalEscape, true);
      break;
    }
    case Op_CastPP:
    case Op_CheckCastPP:
    case Op_EncodeP:
    case Op_DecodeN:
    {
      add_node(n, PointsToNode::LocalVar, PointsToNode::UnknownEscape, false);
      int ti = n->in(1)->_idx;
      PointsToNode::NodeType nt = ptnode_adr(ti)->node_type();
      if (nt == PointsToNode::UnknownType) {
        _delayed_worklist.push(n); // Process it later.
        break;
      } else if (nt == PointsToNode::JavaObject) {
        add_pointsto_edge(n->_idx, ti);
      } else {
        add_deferred_edge(n->_idx, ti);
      }
      _processed.set(n->_idx);
      break;
    }
    case Op_ConP:
    {
      // assume all pointer constants globally escape except for null
      PointsToNode::EscapeState es;
      if (phase->type(n) == TypePtr::NULL_PTR)
        es = PointsToNode::NoEscape;
      else
        es = PointsToNode::GlobalEscape;

      add_node(n, PointsToNode::JavaObject, es, true);
      break;
    }
    case Op_ConN:
    {
      // assume all narrow oop constants globally escape except for null
      PointsToNode::EscapeState es;
      if (phase->type(n) == TypeNarrowOop::NULL_PTR)
        es = PointsToNode::NoEscape;
      else
        es = PointsToNode::GlobalEscape;

      add_node(n, PointsToNode::JavaObject, es, true);
      break;
    }
    case Op_CreateEx:
    {
      // assume that all exception objects globally escape
      add_node(n, PointsToNode::JavaObject, PointsToNode::GlobalEscape, true);
      break;
    }
    case Op_LoadKlass:
    case Op_LoadNKlass:
    {
      add_node(n, PointsToNode::JavaObject, PointsToNode::GlobalEscape, true);
      break;
    }
    case Op_LoadP:
    case Op_LoadN:
    {
      const Type *t = phase->type(n);
      if (t->make_ptr() == NULL) {
        _processed.set(n->_idx);
        return;
      }
      add_node(n, PointsToNode::LocalVar, PointsToNode::UnknownEscape, false);
      break;
    }
    case Op_Parm:
    {
      _processed.set(n->_idx); // No need to redefine it state.
      uint con = n->as_Proj()->_con;
      if (con < TypeFunc::Parms)
        return;
      const Type *t = n->in(0)->as_Start()->_domain->field_at(con);
      if (t->isa_ptr() == NULL)
        return;
      // We have to assume all input parameters globally escape
      // (Note: passing 'false' since _processed is already set).
      add_node(n, PointsToNode::JavaObject, PointsToNode::GlobalEscape, false);
      break;
    }
    case Op_Phi:
    {
      const Type *t = n->as_Phi()->type();
      if (t->make_ptr() == NULL) {
        // nothing to do if not an oop or narrow oop
        _processed.set(n->_idx);
        return;
      }
      add_node(n, PointsToNode::LocalVar, PointsToNode::UnknownEscape, false);
      uint i;
      for (i = 1; i < n->req() ; i++) {
        Node* in = n->in(i);
        if (in == NULL)
          continue;  // ignore NULL
        in = in->uncast();
        if (in->is_top() || in == n)
          continue;  // ignore top or inputs which go back this node
        int ti = in->_idx;
        PointsToNode::NodeType nt = ptnode_adr(ti)->node_type();
        if (nt == PointsToNode::UnknownType) {
          break;
        } else if (nt == PointsToNode::JavaObject) {
          add_pointsto_edge(n->_idx, ti);
        } else {
          add_deferred_edge(n->_idx, ti);
        }
      }
      if (i >= n->req())
        _processed.set(n->_idx);
      else
        _delayed_worklist.push(n);
      break;
    }
    case Op_Proj:
    {
      // we are only interested in the oop result projection from a call
      if (n->as_Proj()->_con == TypeFunc::Parms && n->in(0)->is_Call() ) {
        const TypeTuple *r = n->in(0)->as_Call()->tf()->range();
        assert(r->cnt() > TypeFunc::Parms, "sanity");
        if (r->field_at(TypeFunc::Parms)->isa_ptr() != NULL) {
          add_node(n, PointsToNode::LocalVar, PointsToNode::UnknownEscape, false);
          int ti = n->in(0)->_idx;
          // The call may not be registered yet (since not all its inputs are registered)
          // if this is the projection from backbranch edge of Phi.
          if (ptnode_adr(ti)->node_type() != PointsToNode::UnknownType) {
            process_call_result(n->as_Proj(), phase);
          }
          if (!_processed.test(n->_idx)) {
            // The call's result may need to be processed later if the call
            // returns it's argument and the argument is not processed yet.
            _delayed_worklist.push(n);
          }
          break;
        }
      }
      _processed.set(n->_idx);
      break;
    }
    case Op_Return:
    {
      if( n->req() > TypeFunc::Parms &&
          phase->type(n->in(TypeFunc::Parms))->isa_oopptr() ) {
        // Treat Return value as LocalVar with GlobalEscape escape state.
        add_node(n, PointsToNode::LocalVar, PointsToNode::GlobalEscape, false);
        int ti = n->in(TypeFunc::Parms)->_idx;
        PointsToNode::NodeType nt = ptnode_adr(ti)->node_type();
        if (nt == PointsToNode::UnknownType) {
          _delayed_worklist.push(n); // Process it later.
          break;
        } else if (nt == PointsToNode::JavaObject) {
          add_pointsto_edge(n->_idx, ti);
        } else {
          add_deferred_edge(n->_idx, ti);
        }
      }
      _processed.set(n->_idx);
      break;
    }
    case Op_StoreP:
    case Op_StoreN:
    {
      const Type *adr_type = phase->type(n->in(MemNode::Address));
      adr_type = adr_type->make_ptr();
      if (adr_type->isa_oopptr()) {
        add_node(n, PointsToNode::UnknownType, PointsToNode::UnknownEscape, false);
      } else {
        Node* adr = n->in(MemNode::Address);
        if (adr->is_AddP() && phase->type(adr) == TypeRawPtr::NOTNULL &&
            adr->in(AddPNode::Address)->is_Proj() &&
            adr->in(AddPNode::Address)->in(0)->is_Allocate()) {
          add_node(n, PointsToNode::UnknownType, PointsToNode::UnknownEscape, false);
          // We are computing a raw address for a store captured
          // by an Initialize compute an appropriate address type.
          int offs = (int)phase->find_intptr_t_con(adr->in(AddPNode::Offset), Type::OffsetBot);
          assert(offs != Type::OffsetBot, "offset must be a constant");
        } else {
          _processed.set(n->_idx);
          return;
        }
      }
      break;
    }
    case Op_StorePConditional:
    case Op_CompareAndSwapP:
    case Op_CompareAndSwapN:
    {
      const Type *adr_type = phase->type(n->in(MemNode::Address));
      adr_type = adr_type->make_ptr();
      if (adr_type->isa_oopptr()) {
        add_node(n, PointsToNode::UnknownType, PointsToNode::UnknownEscape, false);
      } else {
        _processed.set(n->_idx);
        return;
      }
      break;
    }
    case Op_AryEq:
    case Op_StrComp:
    case Op_StrEquals:
    case Op_StrIndexOf:
    {
      // char[] arrays passed to string intrinsics are not scalar replaceable.
      add_node(n, PointsToNode::UnknownType, PointsToNode::UnknownEscape, false);
      break;
    }
    case Op_ThreadLocal:
    {
      add_node(n, PointsToNode::JavaObject, PointsToNode::ArgEscape, true);
      break;
    }
    default:
      ;
      // nothing to do
  }
  return;
}

void ConnectionGraph::build_connection_graph(Node *n, PhaseTransform *phase) {
  uint n_idx = n->_idx;
  assert(ptnode_adr(n_idx)->_node != NULL, "node should be registered");

  // Don't set processed bit for AddP, LoadP, StoreP since
  // they may need more then one pass to process.
  // Also don't mark as processed Call nodes since their
  // arguments may need more then one pass to process.
  if (_processed.test(n_idx))
    return; // No need to redefine node's state.

  if (n->is_Call()) {
    CallNode *call = n->as_Call();
    process_call_arguments(call, phase);
    return;
  }

  switch (n->Opcode()) {
    case Op_AddP:
    {
      Node *base = get_addp_base(n);
      // Create a field edge to this node from everything base could point to.
      VectorSet ptset(Thread::current()->resource_area());
      PointsTo(ptset, base);
      for( VectorSetI i(&ptset); i.test(); ++i ) {
        uint pt = i.elem;
        add_field_edge(pt, n_idx, address_offset(n, phase));
      }
      break;
    }
    case Op_CastX2P:
    {
      assert(false, "Op_CastX2P");
      break;
    }
    case Op_CastPP:
    case Op_CheckCastPP:
    case Op_EncodeP:
    case Op_DecodeN:
    {
      int ti = n->in(1)->_idx;
      assert(ptnode_adr(ti)->node_type() != PointsToNode::UnknownType, "all nodes should be registered");
      if (ptnode_adr(ti)->node_type() == PointsToNode::JavaObject) {
        add_pointsto_edge(n_idx, ti);
      } else {
        add_deferred_edge(n_idx, ti);
      }
      _processed.set(n_idx);
      break;
    }
    case Op_ConP:
    {
      assert(false, "Op_ConP");
      break;
    }
    case Op_ConN:
    {
      assert(false, "Op_ConN");
      break;
    }
    case Op_CreateEx:
    {
      assert(false, "Op_CreateEx");
      break;
    }
    case Op_LoadKlass:
    case Op_LoadNKlass:
    {
      assert(false, "Op_LoadKlass");
      break;
    }
    case Op_LoadP:
    case Op_LoadN:
    {
      const Type *t = phase->type(n);
#ifdef ASSERT
      if (t->make_ptr() == NULL)
        assert(false, "Op_LoadP");
#endif

      Node* adr = n->in(MemNode::Address)->uncast();
      Node* adr_base;
      if (adr->is_AddP()) {
        adr_base = get_addp_base(adr);
      } else {
        adr_base = adr;
      }

      // For everything "adr_base" could point to, create a deferred edge from
      // this node to each field with the same offset.
      VectorSet ptset(Thread::current()->resource_area());
      PointsTo(ptset, adr_base);
      int offset = address_offset(adr, phase);
      for( VectorSetI i(&ptset); i.test(); ++i ) {
        uint pt = i.elem;
        add_deferred_edge_to_fields(n_idx, pt, offset);
      }
      break;
    }
    case Op_Parm:
    {
      assert(false, "Op_Parm");
      break;
    }
    case Op_Phi:
    {
#ifdef ASSERT
      const Type *t = n->as_Phi()->type();
      if (t->make_ptr() == NULL)
        assert(false, "Op_Phi");
#endif
      for (uint i = 1; i < n->req() ; i++) {
        Node* in = n->in(i);
        if (in == NULL)
          continue;  // ignore NULL
        in = in->uncast();
        if (in->is_top() || in == n)
          continue;  // ignore top or inputs which go back this node
        int ti = in->_idx;
        PointsToNode::NodeType nt = ptnode_adr(ti)->node_type();
        assert(nt != PointsToNode::UnknownType, "all nodes should be known");
        if (nt == PointsToNode::JavaObject) {
          add_pointsto_edge(n_idx, ti);
        } else {
          add_deferred_edge(n_idx, ti);
        }
      }
      _processed.set(n_idx);
      break;
    }
    case Op_Proj:
    {
      // we are only interested in the oop result projection from a call
      if (n->as_Proj()->_con == TypeFunc::Parms && n->in(0)->is_Call() ) {
        assert(ptnode_adr(n->in(0)->_idx)->node_type() != PointsToNode::UnknownType,
               "all nodes should be registered");
        const TypeTuple *r = n->in(0)->as_Call()->tf()->range();
        assert(r->cnt() > TypeFunc::Parms, "sanity");
        if (r->field_at(TypeFunc::Parms)->isa_ptr() != NULL) {
          process_call_result(n->as_Proj(), phase);
          assert(_processed.test(n_idx), "all call results should be processed");
          break;
        }
      }
      assert(false, "Op_Proj");
      break;
    }
    case Op_Return:
    {
#ifdef ASSERT
      if( n->req() <= TypeFunc::Parms ||
          !phase->type(n->in(TypeFunc::Parms))->isa_oopptr() ) {
        assert(false, "Op_Return");
      }
#endif
      int ti = n->in(TypeFunc::Parms)->_idx;
      assert(ptnode_adr(ti)->node_type() != PointsToNode::UnknownType, "node should be registered");
      if (ptnode_adr(ti)->node_type() == PointsToNode::JavaObject) {
        add_pointsto_edge(n_idx, ti);
      } else {
        add_deferred_edge(n_idx, ti);
      }
      _processed.set(n_idx);
      break;
    }
    case Op_StoreP:
    case Op_StoreN:
    case Op_StorePConditional:
    case Op_CompareAndSwapP:
    case Op_CompareAndSwapN:
    {
      Node *adr = n->in(MemNode::Address);
      const Type *adr_type = phase->type(adr)->make_ptr();
#ifdef ASSERT
      if (!adr_type->isa_oopptr())
        assert(phase->type(adr) == TypeRawPtr::NOTNULL, "Op_StoreP");
#endif

      assert(adr->is_AddP(), "expecting an AddP");
      Node *adr_base = get_addp_base(adr);
      Node *val = n->in(MemNode::ValueIn)->uncast();
      // For everything "adr_base" could point to, create a deferred edge
      // to "val" from each field with the same offset.
      VectorSet ptset(Thread::current()->resource_area());
      PointsTo(ptset, adr_base);
      for( VectorSetI i(&ptset); i.test(); ++i ) {
        uint pt = i.elem;
        add_edge_from_fields(pt, val->_idx, address_offset(adr, phase));
      }
      break;
    }
    case Op_AryEq:
    case Op_StrComp:
    case Op_StrEquals:
    case Op_StrIndexOf:
    {
      // char[] arrays passed to string intrinsic do not escape but
      // they are not scalar replaceable. Adjust escape state for them.
      // Start from in(2) edge since in(1) is memory edge.
      for (uint i = 2; i < n->req(); i++) {
        Node* adr = n->in(i)->uncast();
        const Type *at = phase->type(adr);
        if (!adr->is_top() && at->isa_ptr()) {
          assert(at == Type::TOP || at == TypePtr::NULL_PTR ||
                 at->isa_ptr() != NULL, "expecting an Ptr");
          if (adr->is_AddP()) {
            adr = get_addp_base(adr);
          }
          // Mark as ArgEscape everything "adr" could point to.
          set_escape_state(adr->_idx, PointsToNode::ArgEscape);
        }
      }
      _processed.set(n_idx);
      break;
    }
    case Op_ThreadLocal:
    {
      assert(false, "Op_ThreadLocal");
      break;
    }
    default:
      // This method should be called only for EA specific nodes.
      ShouldNotReachHere();
  }
}

#ifndef PRODUCT
void ConnectionGraph::dump() {
  bool first = true;

  uint size = nodes_size();
  for (uint ni = 0; ni < size; ni++) {
    PointsToNode *ptn = ptnode_adr(ni);
    PointsToNode::NodeType ptn_type = ptn->node_type();

    if (ptn_type != PointsToNode::JavaObject || ptn->_node == NULL)
      continue;
    PointsToNode::EscapeState es = escape_state(ptn->_node);
    if (ptn->_node->is_Allocate() && (es == PointsToNode::NoEscape || Verbose)) {
      if (first) {
        tty->cr();
        tty->print("======== Connection graph for ");
        _compile->method()->print_short_name();
        tty->cr();
        first = false;
      }
      tty->print("%6d ", ni);
      ptn->dump();
      // Print all locals which reference this allocation
      for (uint li = ni; li < size; li++) {
        PointsToNode *ptn_loc = ptnode_adr(li);
        PointsToNode::NodeType ptn_loc_type = ptn_loc->node_type();
        if ( ptn_loc_type == PointsToNode::LocalVar && ptn_loc->_node != NULL &&
             ptn_loc->edge_count() == 1 && ptn_loc->edge_target(0) == ni ) {
          ptnode_adr(li)->dump(false);
        }
      }
      if (Verbose) {
        // Print all fields which reference this allocation
        for (uint i = 0; i < ptn->edge_count(); i++) {
          uint ei = ptn->edge_target(i);
          ptnode_adr(ei)->dump(false);
        }
      }
      tty->cr();
    }
  }
}
#endif