escape.cpp 75.6 KB
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/*
 * Copyright 2005-2006 Sun Microsystems, Inc.  All Rights Reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.
 *
 * This code is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 *
 * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
 * CA 95054 USA or visit www.sun.com if you need additional information or
 * have any questions.
 *
 */

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

uint PointsToNode::edge_target(uint e) const {
  assert(_edges != NULL && e < (uint)_edges->length(), "valid edge index");
  return (_edges->at(e) >> EdgeShift);
}

PointsToNode::EdgeType PointsToNode::edge_type(uint e) const {
  assert(_edges != NULL && e < (uint)_edges->length(), "valid edge index");
  return (EdgeType) (_edges->at(e) & EdgeMask);
}

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

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

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

void PointsToNode::dump() const {
  NodeType nt = node_type();
  EscapeState es = escape_state();
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  tty->print("%s %s %s [[", node_type_names[(int) nt], esc_names[(int) es], _scalar_replaceable ? "" : "NSR");
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  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) : _processed(C->comp_arena()), _node_map(C->comp_arena()) {
  _collecting = true;
  this->_compile = C;
  const PointsToNode &dummy = PointsToNode();
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  int sz = C->unique();
  _nodes = new(C->comp_arena()) GrowableArray<PointsToNode>(C->comp_arena(), sz, sz, dummy);
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  _phantom_object = C->top()->_idx;
  PointsToNode *phn = ptnode_adr(_phantom_object);
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  phn->_node = C->top();
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  phn->set_node_type(PointsToNode::JavaObject);
  phn->set_escape_state(PointsToNode::GlobalEscape);
}

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");
  f->add_edge(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)
    f->add_edge(to_i, PointsToNode::DeferredEdge);
}

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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();
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  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);

  f->add_edge(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);
}

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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);
}

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

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

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

  es = _nodes->at_grow(idx).escape_state();

  // if we have already computed a value, return it
  if (es != PointsToNode::UnknownEscape)
    return es;

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

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

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  n = n->uncast();
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  PointsToNode  npt = _nodes->at_grow(n->_idx);

  // If we have a JavaObject, return just that object
  if (npt.node_type() == PointsToNode::JavaObject) {
    ptset.set(n->_idx);
    return;
  }
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  assert(npt._node != NULL, "unregistered node");

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  worklist.push(n->_idx);
  while(worklist.length() > 0) {
    int ni = worklist.pop();
    PointsToNode pn = _nodes->at_grow(ni);
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    if (!visited.test_set(ni)) {
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      // ensure that all inputs of a Phi have been processed
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      assert(!_collecting || !pn._node->is_Phi() || _processed.test(ni),"");
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      int edges_processed = 0;
      for (uint e = 0; e < pn.edge_count(); e++) {
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        uint etgt = pn.edge_target(e);
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        PointsToNode::EdgeType et = pn.edge_type(e);
        if (et == PointsToNode::PointsToEdge) {
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          ptset.set(etgt);
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          edges_processed++;
        } else if (et == PointsToNode::DeferredEdge) {
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          worklist.push(etgt);
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          edges_processed++;
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        } else {
          assert(false,"neither PointsToEdge or DeferredEdge");
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        }
      }
      if (edges_processed == 0) {
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        // no deferred or pointsto edges found.  Assume the value was set
        // outside this method.  Add the phantom object to the pointsto set.
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        ptset.set(_phantom_object);
      }
    }
  }
}

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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();
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  uint i = 0;
  PointsToNode *ptn = ptnode_adr(ni);

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  // Mark current edges as visited and move deferred edges to separate array.
  for (; i < ptn->edge_count(); i++) {
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    uint t = ptn->edge_target(i);
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#ifdef ASSERT
    assert(!visited->test_set(t), "expecting no duplications");
#else
    visited->set(t);
#endif
    if (ptn->edge_type(i) == PointsToNode::DeferredEdge) {
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      ptn->remove_edge(t, PointsToNode::DeferredEdge);
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      deferred_edges->append(t);
    }
  }
  for (int next = 0; next < deferred_edges->length(); ++next) {
    uint t = deferred_edges->at(next);
    PointsToNode *ptt = ptnode_adr(t);
    for (uint j = 0; j < ptt->edge_count(); j++) {
      uint n1 = ptt->edge_target(j);
      if (visited->test_set(n1))
        continue;
      switch(ptt->edge_type(j)) {
        case PointsToNode::PointsToEdge:
          add_pointsto_edge(ni, n1);
          if(n1 == _phantom_object) {
            // Special case - field set outside (globally escaping).
            ptn->set_escape_state(PointsToNode::GlobalEscape);
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          }
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          break;
        case PointsToNode::DeferredEdge:
          deferred_edges->append(n1);
          break;
        case PointsToNode::FieldEdge:
          assert(false, "invalid connection graph");
          break;
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      }
    }
  }
}


//  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 = _nodes->at_grow(adr_i);
  PointsToNode to = _nodes->at_grow(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 = _nodes->at_grow(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);
    }
  }
}

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// Add a deferred  edge from node given by "from_i" to any field of adr_i
// whose offset matches "offset".
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void ConnectionGraph::add_deferred_edge_to_fields(uint from_i, uint adr_i, int offs) {
  PointsToNode an = _nodes->at_grow(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 = _nodes->at_grow(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);
    }
  }
}

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// 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 )
  //
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  // case #6. Constant Pool, ThreadLocal, CastX2P or
  //          Raw object's field reference:
  //      {ConP, ThreadLocal, CastX2P, raw Load}
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  //  top   |
  //     \  |
  //     AddP  ( base == top )
  //
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  // case #7. Klass's field reference.
  //      LoadKlass
  //       | |
  //       AddP  ( base == address )
  //
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  Node *base = addp->in(AddPNode::Base)->uncast();
  if (base->is_top()) { // The AddP case #3 and #6.
    base = addp->in(AddPNode::Address)->uncast();
    assert(base->Opcode() == Op_ConP || base->Opcode() == Op_ThreadLocal ||
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           base->Opcode() == Op_CastX2P ||
           (base->is_Mem() && base->bottom_type() == TypeRawPtr::NOTNULL) ||
           (base->is_Proj() && base->in(0)->is_Allocate()), "sanity");
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  }
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  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;
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}

//
// Adjust the type and inputs of an AddP which computes the
// address of a field of an instance
//
void 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_instance(), "expecting instance oopptr");
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  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.
    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");
    int 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();
  }
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  uint inst_id =  base_t->instance_id();
  assert(!t->is_instance() || t->instance_id() == inst_id,
                             "old type must be non-instance or match new type");
  const TypeOopPtr *tinst = base_t->add_offset(t->offset())->is_oopptr();
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  // Do NOT remove the next call: ensure an new alias index is allocated
  // for the instance type
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  int alias_idx = _compile->get_alias_index(tinst);
  igvn->set_type(addp, tinst);
  // record the allocation in the node map
  set_map(addp->_idx, get_map(base->_idx));
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  // if the Address input is not the appropriate instance type
  // (due to intervening casts,) insert a cast
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  Node *adr = addp->in(AddPNode::Address);
  const TypeOopPtr  *atype = igvn->type(adr)->isa_oopptr();
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  if (atype != NULL && atype->instance_id() != inst_id) {
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    assert(!atype->is_instance(), "no conflicting instances");
    const TypeOopPtr *new_atype = base_t->add_offset(atype->offset())->isa_oopptr();
    Node *acast = new (_compile, 2) CastPPNode(adr, new_atype);
    acast->set_req(0, adr->in(0));
    igvn->set_type(acast, new_atype);
    record_for_optimizer(acast);
    Node *bcast = acast;
    Node *abase = addp->in(AddPNode::Base);
    if (abase != adr) {
      bcast = new (_compile, 2) CastPPNode(abase, base_t);
      bcast->set_req(0, abase->in(0));
      igvn->set_type(bcast, base_t);
      record_for_optimizer(bcast);
    }
    igvn->hash_delete(addp);
    addp->set_req(AddPNode::Base, bcast);
    addp->set_req(AddPNode::Address, acast);
    igvn->hash_insert(addp);
  }
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  // Put on IGVN worklist since at least addp's type was changed above.
  record_for_optimizer(addp);
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}

//
// 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
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  if (phi_alias_idx == alias_idx) {
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    return orig_phi;
  }
  // have we already 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;
  }
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  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;
  }
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  orig_phi_worklist.append_if_missing(orig_phi);
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  const TypePtr *atype = C->get_adr_type(alias_idx);
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  result = PhiNode::make(orig_phi->in(0), NULL, Type::MEMORY, atype);
  set_map_phi(orig_phi->_idx, result);
  igvn->set_type(result, result->bottom_type());
  record_for_optimizer(result);
  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;
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  PhiNode *result = create_split_phi(orig_phi, alias_idx, orig_phi_worklist, igvn, new_phi_created);
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  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()) {
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      Node *mem = find_inst_mem(phi->in(idx), alias_idx, orig_phi_worklist, igvn);
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      if (mem != NULL && mem->is_Phi()) {
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        PhiNode *newphi = create_split_phi(mem->as_Phi(), alias_idx, orig_phi_worklist, igvn, new_phi_created);
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        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();
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          result = newphi;
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          idx = 1;
          continue;
        } else {
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          mem = newphi;
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        }
      }
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      if (C->failing()) {
        return NULL;
      }
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      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");
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#endif
    // Check if all new phi's inputs have specified alias index.
    // Otherwise use old phi.
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    for (uint i = 1; i < phi->req(); i++) {
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      Node* in = result->in(i);
      assert((phi->in(i) == NULL) == (in == NULL), "inputs must correspond.");
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    }
    // 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();
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      PhiNode *prev_result = get_map_phi(phi->_idx);
      prev_result->set_req(idx++, result);
      result = prev_result;
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    }
  }
  return result;
}

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//
// The next methods are derived from methods in MemNode.
//
static Node *step_through_mergemem(MergeMemNode *mmem, int alias_idx, const TypeOopPtr *tinst) {
  Node *mem = mmem;
  // TypeInstPtr::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( tinst->base() != Type::AnyPtr &&
      !(tinst->klass()->is_java_lang_Object() &&
        tinst->offset() == Type::OffsetBot) ) {
    mem = mmem->memory_at(alias_idx);
    // Update input if it is progress over what we have now
  }
  return mem;
}

//
// 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 *tinst = C->get_adr_type(alias_idx)->isa_oopptr();
  bool is_instance = (tinst != NULL) && tinst->is_instance();
  Node *prev = NULL;
  Node *result = orig_mem;
  while (prev != result) {
    prev = result;
    if (result->is_Mem()) {
      MemNode *mem = result->as_Mem();
      const Type *at = phase->type(mem->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 = mem->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_Call()) {
        CallNode *call = proj_in->as_Call();
        if (!call->may_modify(tinst, 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 != tinst->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, tinst);
      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) {
        result = un;
      } else {
        break;
      }
    }
  }
  if (is_instance && 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) {
      result = split_memory_phi(mphi, alias_idx, orig_phis, phase);
    }
  }
  // the result is either MemNode, PhiNode, InitializeNode.
  return result;
}


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//
//  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 approriate 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<Node *>  mergemem_worklist;
  GrowableArray<PhiNode *>  orig_phis;
  PhaseGVN  *igvn = _compile->initial_gvn();
  uint new_index_start = (uint) _compile->num_alias_types();
  VectorSet visited(Thread::current()->resource_area());
  VectorSet ptset(Thread::current()->resource_area());

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  //  Phase 1:  Process possible allocations from alloc_worklist.
  //  Create instance types for the CheckCastPP for allocations where possible.
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  while (alloc_worklist.length() != 0) {
    Node *n = alloc_worklist.pop();
    uint ni = n->_idx;
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    const TypeOopPtr* tinst = NULL;
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    if (n->is_Call()) {
      CallNode *alloc = n->as_Call();
      // copy escape information to call node
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      PointsToNode* ptn = _nodes->adr_at(alloc->_idx);
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      PointsToNode::EscapeState es = escape_state(alloc, igvn);
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      // We have an allocation or call which returns a Java object,
      // see if it is unescaped.
      if (es != PointsToNode::NoEscape || !ptn->_scalar_replaceable)
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        continue;
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      if (alloc->is_Allocate()) {
        // Set the scalar_replaceable flag before the next check.
        alloc->as_Allocate()->_is_scalar_replaceable = true;
      }
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      // find CheckCastPP of call return value
      n = alloc->result_cast();
      if (n == NULL ||          // No uses accept Initialize or
          !n->is_CheckCastPP()) // not unique CheckCastPP.
        continue;
      // The inline code for Object.clone() casts the allocation result to
      // java.lang.Object and then to the the actual type of the allocated
      // object. Detect this case and use the second cast.
      if (alloc->is_Allocate() && n->as_Type()->type() == TypeInstPtr::NOTNULL
          && 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 {
          continue;
        }
      }
      set_escape_state(n->_idx, es);
      // in order for an object to be stackallocatable, 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
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      set_map(alloc->_idx, n);
      set_map(n->_idx, alloc);
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      const TypeOopPtr *t = igvn->type(n)->isa_oopptr();
      if (t == NULL)
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        continue;  // not a TypeInstPtr
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      tinst = t->cast_to_instance(ni);
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      igvn->hash_delete(n);
      igvn->set_type(n,  tinst);
      n->raise_bottom_type(tinst);
      igvn->hash_insert(n);
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      record_for_optimizer(n);
      if (alloc->is_Allocate() && ptn->_scalar_replaceable &&
          (t->isa_instptr() || t->isa_aryptr())) {
        // 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_Initialize()) {
            memnode_worklist.append_if_missing(use);
          }
        }
      }
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    } else if (n->is_AddP()) {
      ptset.Clear();
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      PointsTo(ptset, get_addp_base(n), igvn);
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      assert(ptset.Size() == 1, "AddP address is unique");
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      uint elem = ptset.getelem(); // Allocation node's index
      if (elem == _phantom_object)
        continue; // Assume the value was set outside this method.
      Node *base = get_map(elem);  // CheckCastPP node
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      split_AddP(n, base, igvn);
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      tinst = igvn->type(base)->isa_oopptr();
    } else if (n->is_Phi() ||
               n->is_CheckCastPP() ||
               (n->is_ConstraintCast() && n->Opcode() == Op_CastPP)) {
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      if (visited.test_set(n->_idx)) {
        assert(n->is_Phi(), "loops only through Phi's");
        continue;  // already processed
      }
      ptset.Clear();
      PointsTo(ptset, n, igvn);
      if (ptset.Size() == 1) {
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        uint elem = ptset.getelem(); // Allocation node's index
        if (elem == _phantom_object)
          continue; // Assume the value was set outside this method.
        Node *val = get_map(elem);   // CheckCastPP node
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        TypeNode *tn = n->as_Type();
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        tinst = igvn->type(val)->isa_oopptr();
        assert(tinst != NULL && tinst->is_instance() &&
               tinst->instance_id() == elem , "instance type expected.");
        const TypeOopPtr *tn_t = igvn->type(tn)->isa_oopptr();
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        if (tn_t != NULL &&
 tinst->cast_to_instance(TypeOopPtr::UNKNOWN_INSTANCE)->higher_equal(tn_t)) {
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          igvn->hash_delete(tn);
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          igvn->set_type(tn, tinst);
          tn->set_type(tinst);
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          igvn->hash_insert(tn);
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          record_for_optimizer(n);
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        }
      }
    } else {
      continue;
    }
    // push 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) {
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        memnode_worklist.append_if_missing(use);
      } else if (use->is_Initialize()) {
        memnode_worklist.append_if_missing(use);
      } else if (use->is_MergeMem()) {
        mergemem_worklist.append_if_missing(use);
      } else if (use->is_Call() && tinst != NULL) {
        // Look for MergeMem nodes for calls which reference unique allocation
        // (through CheckCastPP nodes) even for debug info.
        Node* m = use->in(TypeFunc::Memory);
        uint iid = tinst->instance_id();
        while (m->is_Proj() && m->in(0)->is_Call() &&
               m->in(0) != use && !m->in(0)->_idx != iid) {
          m = m->in(0)->in(TypeFunc::Memory);
        }
        if (m->is_MergeMem()) {
          mergemem_worklist.append_if_missing(m);
        }
      } 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_ConstraintCast() && use->Opcode() == Op_CastPP)) {
        alloc_worklist.append_if_missing(use);
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      }
    }

  }
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  // New alias types were created in split_AddP().
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  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();
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    if (visited.test_set(n->_idx))
      continue;
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    if (n->is_Phi()) {
      assert(n->as_Phi()->adr_type() != TypePtr::BOTTOM, "narrow memory slice required");
      // we don't need to do anything, but the users must be pushed if we haven't processed
      // this Phi before
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    } else if (n->is_Initialize()) {
      // we don't need to do anything, but the users of the memory projection must be pushed
      n = n->as_Initialize()->proj_out(TypeFunc::Memory);
      if (n == NULL)
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        continue;
    } else {
      assert(n->is_Mem(), "memory node required.");
      Node *addr = n->in(MemNode::Address);
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      assert(addr->is_AddP(), "AddP required");
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      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());
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      assert ((uint)alias_idx < new_index_end, "wrong alias index");
      Node *mem = find_inst_mem(n->in(MemNode::Memory), alias_idx, orig_phis, igvn);
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      if (_compile->failing()) {
        return;
      }
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      if (mem != n->in(MemNode::Memory)) {
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        set_map(n->_idx, mem);
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        _nodes->adr_at(n->_idx)->_node = n;
      }
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      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()) {
1033
        memnode_worklist.append_if_missing(use);
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      } else if(use->is_Mem() && use->in(MemNode::Memory) == n) {
1035 1036 1037
        memnode_worklist.append_if_missing(use);
      } else if (use->is_Initialize()) {
        memnode_worklist.append_if_missing(use);
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      } else if (use->is_MergeMem()) {
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        mergemem_worklist.append_if_missing(use);
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      }
    }
  }

1044 1045 1046
  //  Phase 3:  Process MergeMem nodes from mergemem_worklist.
  //            Walk each memory moving the first node encountered of each
  //            instance type to the the input corresponding to its alias index.
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  while (mergemem_worklist.length() != 0) {
    Node *n = mergemem_worklist.pop();
    assert(n->is_MergeMem(), "MergeMem node required.");
1050 1051
    if (visited.test_set(n->_idx))
      continue;
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    MergeMemNode *nmm = n->as_MergeMem();
    // Note: we don't want to use MergeMemStream here because we only want to
1054
    //  scan inputs which exist at the start, not ones we add during processing.
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    uint nslices = nmm->req();
    igvn->hash_delete(nmm);
    for (uint i = Compile::AliasIdxRaw+1; i < nslices; i++) {
1058 1059
      Node* mem = nmm->in(i);
      Node* cur = NULL;
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      if (mem == NULL || mem->is_top())
        continue;
      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);
1079 1080 1081 1082 1083 1084 1085 1086 1087
      // Find any instance of the current type if we haven't encountered
      // a value of the instance along the 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;
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            }
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            nmm->set_memory_at(ni, result);
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          }
        }
      }
    }
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    // Find the rest of instances values
    for (uint ni = new_index_start; ni < new_index_end; ni++) {
      const TypeOopPtr *tinst = igvn->C->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(igvn->C->get_general_index(ni));
        result = find_inst_mem(result, ni, orig_phis, igvn);
        if (_compile->failing()) {
          return;
        }
        nmm->set_memory_at(ni, result);
      }
    }
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    igvn->hash_insert(nmm);
    record_for_optimizer(nmm);
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    // Propagate new memory slices to following MergeMem nodes.
    for (DUIterator_Fast imax, i = n->fast_outs(imax); i < imax; i++) {
      Node *use = n->fast_out(i);
      if (use->is_Call()) {
        CallNode* in = use->as_Call();
        if (in->proj_out(TypeFunc::Memory) != NULL) {
          Node* m = in->proj_out(TypeFunc::Memory);
          for (DUIterator_Fast jmax, j = m->fast_outs(jmax); j < jmax; j++) {
            Node* mm = m->fast_out(j);
            if (mm->is_MergeMem()) {
              mergemem_worklist.append_if_missing(mm);
            }
          }
        }
        if (use->is_Allocate()) {
          use = use->as_Allocate()->initialization();
          if (use == NULL) {
            continue;
          }
        }
      }
      if (use->is_Initialize()) {
        InitializeNode* in = use->as_Initialize();
        if (in->proj_out(TypeFunc::Memory) != NULL) {
          Node* m = in->proj_out(TypeFunc::Memory);
          for (DUIterator_Fast jmax, j = m->fast_outs(jmax); j < jmax; j++) {
            Node* mm = m->fast_out(j);
            if (mm->is_MergeMem()) {
              mergemem_worklist.append_if_missing(mm);
            }
          }
        }
      }
    }
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  }

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  //  Phase 4:  Update the inputs of non-instance memory Phis and
  //            the Memory input of memnodes
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  // 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.
  while (orig_phis.length() != 0) {
    PhiNode *phi = orig_phis.pop();
    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);
1160 1161 1162 1163
      Node *new_mem = find_inst_mem(mem, alias_idx, orig_phis, igvn);
      if (_compile->failing()) {
        return;
      }
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      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.
  for (int i = 0; i < _nodes->length(); i++) {
    Node *nmem = get_map(i);
    if (nmem != NULL) {
1177
      Node *n = _nodes->adr_at(i)->_node;
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      if (n != NULL && n->is_Mem()) {
        igvn->hash_delete(n);
        n->set_req(MemNode::Memory, nmem);
        igvn->hash_insert(n);
        record_for_optimizer(n);
      }
    }
  }
}

void ConnectionGraph::compute_escape() {

1190
  // 1. Populate Connection Graph with Ideal nodes.
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  Unique_Node_List worklist_init;
  worklist_init.map(_compile->unique(), NULL);  // preallocate space

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

  GrowableArray<int> cg_worklist;
  PhaseGVN* igvn = _compile->initial_gvn();
  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);
    if (n->is_Call() &&
        _nodes->adr_at(n->_idx)->node_type() == PointsToNode::JavaObject) {
      has_allocations = true;
    }
    if(n->is_AddP())
      cg_worklist.append(n->_idx);
    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) {
    _has_allocations = true;
  } else {
    _has_allocations = false;
    _collecting = false;
    return; // Nothing to do.
  }

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

  // 3. Pass to create fields edges (Allocate -F-> AddP).
  for( int next = 0; next < cg_worklist.length(); ++next ) {
    int ni = cg_worklist.at(next);
    build_connection_graph(_nodes->adr_at(ni)->_node, igvn);
  }

  cg_worklist.clear();
  cg_worklist.append(_phantom_object);

  // 4. Build Connection Graph which need
  //    to walk the connection graph.
  for (uint ni = 0; ni < (uint)_nodes->length(); ni++) {
    PointsToNode* ptn = _nodes->adr_at(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
    }
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  }

  VectorSet ptset(Thread::current()->resource_area());
1256 1257 1258 1259
  GrowableArray<Node*> alloc_worklist;
  GrowableArray<int>   worklist;
  GrowableArray<uint>  deferred_edges;
  VectorSet visited(Thread::current()->resource_area());
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  // remove deferred edges from the graph and collect
  // information we will need for type splitting
1263 1264 1265
  for( int next = 0; next < cg_worklist.length(); ++next ) {
    int ni = cg_worklist.at(next);
    PointsToNode* ptn = _nodes->adr_at(ni);
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    PointsToNode::NodeType nt = ptn->node_type();
    Node *n = ptn->_node;
    if (nt == PointsToNode::LocalVar || nt == PointsToNode::Field) {
1269
      remove_deferred(ni, &deferred_edges, &visited);
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      if (n->is_AddP()) {
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        // If this AddP computes an address which may point to more that one
        // object, nothing the address points to can be scalar replaceable.
        Node *base = get_addp_base(n);
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        ptset.Clear();
        PointsTo(ptset, base, igvn);
        if (ptset.Size() > 1) {
          for( VectorSetI j(&ptset); j.test(); ++j ) {
1278 1279
            uint pt = j.elem;
            ptnode_adr(pt)->_scalar_replaceable = false;
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          }
        }
      }
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    } else if (nt == PointsToNode::JavaObject && n->is_Call()) {
      // Push call on alloc_worlist (alocations are calls)
      // for processing by split_unique_types().
      alloc_worklist.append(n);
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    }
  }
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  // push all GlobalEscape nodes on the worklist
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  for( int next = 0; next < cg_worklist.length(); ++next ) {
    int nk = cg_worklist.at(next);
    if (_nodes->adr_at(nk)->escape_state() == PointsToNode::GlobalEscape)
      worklist.append(nk);
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  }
  // mark all node reachable from GlobalEscape nodes
  while(worklist.length() > 0) {
    PointsToNode n = _nodes->at(worklist.pop());
    for (uint ei = 0; ei < n.edge_count(); ei++) {
      uint npi = n.edge_target(ei);
      PointsToNode *np = ptnode_adr(npi);
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      if (np->escape_state() < PointsToNode::GlobalEscape) {
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        np->set_escape_state(PointsToNode::GlobalEscape);
        worklist.append_if_missing(npi);
      }
    }
  }

  // push all ArgEscape nodes on the worklist
1310 1311 1312
  for( int next = 0; next < cg_worklist.length(); ++next ) {
    int nk = cg_worklist.at(next);
    if (_nodes->adr_at(nk)->escape_state() == PointsToNode::ArgEscape)
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      worklist.push(nk);
  }
  // mark all node reachable from ArgEscape nodes
  while(worklist.length() > 0) {
    PointsToNode n = _nodes->at(worklist.pop());
    for (uint ei = 0; ei < n.edge_count(); ei++) {
      uint npi = n.edge_target(ei);
      PointsToNode *np = ptnode_adr(npi);
1321
      if (np->escape_state() < PointsToNode::ArgEscape) {
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        np->set_escape_state(PointsToNode::ArgEscape);
        worklist.append_if_missing(npi);
      }
    }
  }

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  // push all NoEscape nodes on the worklist
  for( int next = 0; next < cg_worklist.length(); ++next ) {
    int nk = cg_worklist.at(next);
    if (_nodes->adr_at(nk)->escape_state() == PointsToNode::NoEscape)
      worklist.push(nk);
  }
  // mark all node reachable from NoEscape nodes
  while(worklist.length() > 0) {
    PointsToNode n = _nodes->at(worklist.pop());
    for (uint ei = 0; ei < n.edge_count(); ei++) {
      uint npi = n.edge_target(ei);
      PointsToNode *np = ptnode_adr(npi);
      if (np->escape_state() < PointsToNode::NoEscape) {
        np->set_escape_state(PointsToNode::NoEscape);
        worklist.append_if_missing(npi);
      }
    }
  }
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1347
  _collecting = false;
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1349
  has_allocations = false; // Are there scalar replaceable allocations?
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  for( int next = 0; next < alloc_worklist.length(); ++next ) {
    Node* n = alloc_worklist.at(next);
    uint ni = n->_idx;
    PointsToNode* ptn = _nodes->adr_at(ni);
    PointsToNode::EscapeState es = ptn->escape_state();
    if (ptn->escape_state() == PointsToNode::NoEscape &&
        ptn->_scalar_replaceable) {
      has_allocations = true;
      break;
    }
  }
  if (!has_allocations) {
    return; // Nothing to do.
  }
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1366 1367 1368 1369 1370
  if(_compile->AliasLevel() >= 3 && EliminateAllocations) {
    // Now use the escape information to create unique types for
    // unescaped objects
    split_unique_types(alloc_worklist);
    if (_compile->failing())  return;
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1372 1373 1374
    // Clean up after split unique types.
    ResourceMark rm;
    PhaseRemoveUseless pru(_compile->initial_gvn(), _compile->for_igvn());
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1376 1377 1378 1379 1380 1381 1382 1383
#ifdef ASSERT
  } else if (PrintEscapeAnalysis || PrintEliminateAllocations) {
    tty->print("=== No allocations eliminated for ");
    C()->method()->print_short_name();
    if(!EliminateAllocations) {
      tty->print(" since EliminateAllocations is off ===");
    } else if(_compile->AliasLevel() < 3) {
      tty->print(" since AliasLevel < 3 ===");
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    }
1385 1386
    tty->cr();
#endif
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  }
}

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

    switch (call->Opcode()) {
1393
#ifdef ASSERT
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    case Op_Allocate:
    case Op_AllocateArray:
    case Op_Lock:
    case Op_Unlock:
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      assert(false, "should be done already");
      break;
#endif
    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()) {
          assert(aat == Type::TOP || aat == TypePtr::NULL_PTR ||
                 aat->isa_ptr() != NULL, "expecting an Ptr");
          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, phase);
          for( VectorSetI j(&ptset); j.test(); ++j ) {
            uint pt = j.elem;
            set_escape_state(pt, PointsToNode::ArgEscape);
          }
        }
      }
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      break;
1434
    }
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    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();
1441 1442 1443
      BCEscapeAnalyzer *call_analyzer = (meth !=NULL) ? meth->get_bcea() : NULL;
      // fall-through if not a Java method or no analyzer information
      if (call_analyzer != NULL) {
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        const TypeTuple * d = call->tf()->domain();
        VectorSet ptset(Thread::current()->resource_area());
1446
        bool copy_dependencies = false;
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        for (uint i = TypeFunc::Parms; i < d->cnt(); i++) {
          const Type* at = d->field_at(i);
          int k = i - TypeFunc::Parms;

          if (at->isa_oopptr() != NULL) {
1452
            Node *arg = call->in(i)->uncast();
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1454 1455 1456
            bool global_escapes = false;
            bool fields_escapes = false;
            if (!call_analyzer->is_arg_stack(k)) {
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              // The argument global escapes, mark everything it could point to
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              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;
            }
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            ptset.Clear();
            PointsTo(ptset, arg, phase);
            for( VectorSetI j(&ptset); j.test(); ++j ) {
              uint pt = j.elem;
              if (global_escapes) {
                //The argument global escapes, mark everything it could point to
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                set_escape_state(pt, PointsToNode::GlobalEscape);
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              } 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);
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              }
            }
          }
        }
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        if (copy_dependencies)
          call_analyzer->copy_dependencies(C()->dependencies());
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        break;
      }
    }

    default:
1493 1494
    // Fall-through here if not a Java method or no analyzer information
    // or some other type of call, assume the worst case: all arguments
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    // 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) {
1503 1504
          Node *arg = call->in(i)->uncast();
          set_escape_state(arg->_idx, PointsToNode::GlobalEscape);
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          ptset.Clear();
          PointsTo(ptset, arg, phase);
          for( VectorSetI j(&ptset); j.test(); ++j ) {
            uint pt = j.elem;
            set_escape_state(pt, PointsToNode::GlobalEscape);
1510
            PointsToNode *ptadr = ptnode_adr(pt);
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          }
        }
      }
    }
  }
}
void ConnectionGraph::process_call_result(ProjNode *resproj, PhaseTransform *phase) {
  PointsToNode *ptadr = ptnode_adr(resproj->_idx);

1520
  CallNode *call = resproj->in(0)->as_Call();
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  switch (call->Opcode()) {
    case Op_Allocate:
    {
      Node *k = call->in(AllocateNode::KlassNode);
      const TypeKlassPtr *kt;
      if (k->Opcode() == Op_LoadKlass) {
        kt = k->as_Load()->type()->isa_klassptr();
      } else {
        kt = k->as_Type()->type()->isa_klassptr();
      }
      assert(kt != NULL, "TypeKlassPtr  required.");
      ciKlass* cik = kt->klass();
      ciInstanceKlass* ciik = cik->as_instance_klass();

      PointsToNode *ptadr = ptnode_adr(call->_idx);
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      PointsToNode::EscapeState es;
      uint edge_to;
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      if (cik->is_subclass_of(_compile->env()->Thread_klass()) || ciik->has_finalizer()) {
1539 1540
        es = PointsToNode::GlobalEscape;
        edge_to = _phantom_object; // Could not be worse
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      } else {
1542 1543
        es = PointsToNode::NoEscape;
        edge_to = call->_idx;
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      }
1545 1546 1547
      set_escape_state(call->_idx, es);
      add_pointsto_edge(resproj->_idx, edge_to);
      _processed.set(resproj->_idx);
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1548 1549 1550 1551 1552 1553
      break;
    }

    case Op_AllocateArray:
    {
      PointsToNode *ptadr = ptnode_adr(call->_idx);
1554 1555 1556 1557 1558
      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.
        ptadr->_scalar_replaceable = false;
      }
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      set_escape_state(call->_idx, PointsToNode::NoEscape);
      add_pointsto_edge(resproj->_idx, call->_idx);
1561
      _processed.set(resproj->_idx);
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1562 1563 1564 1565 1566 1567 1568
      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
    {
1569
      bool done = true;
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1570 1571 1572 1573 1574 1575 1576 1577
      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.
1578 1579
      if (ret_type == NULL || ret_type->isa_ptr() == NULL) {
        _processed.set(resproj->_idx);
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        break;  // doesn't return a pointer type
1581
      }
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      ciMethod *meth = call->as_CallJava()->method();
1583
      const TypeTuple * d = call->tf()->domain();
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1584 1585 1586 1587 1588 1589
      if (meth == NULL) {
        // not a Java method, assume global escape
        set_escape_state(call->_idx, PointsToNode::GlobalEscape);
        if (resproj != NULL)
          add_pointsto_edge(resproj->_idx, _phantom_object);
      } else {
1590
        BCEscapeAnalyzer *call_analyzer = meth->get_bcea();
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        VectorSet ptset(Thread::current()->resource_area());
1592
        bool copy_dependencies = false;
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1594 1595 1596 1597 1598 1599 1600 1601 1602 1603
        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);
          if (resproj != NULL)
            add_pointsto_edge(resproj->_idx, call->_idx);
          copy_dependencies = true;
        } else if (call_analyzer->is_return_local() && resproj != NULL) {
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          // determine whether any arguments are returned
          set_escape_state(call->_idx, PointsToNode::NoEscape);
          for (uint i = TypeFunc::Parms; i < d->cnt(); i++) {
            const Type* at = d->field_at(i);

            if (at->isa_oopptr() != NULL) {
1610
              Node *arg = call->in(i)->uncast();
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1611

1612
              if (call_analyzer->is_arg_returned(i - TypeFunc::Parms)) {
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                PointsToNode *arg_esp = _nodes->adr_at(arg->_idx);
1614 1615 1616
                if (arg_esp->node_type() == PointsToNode::UnknownType)
                  done = false;
                else if (arg_esp->node_type() == PointsToNode::JavaObject)
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                  add_pointsto_edge(resproj->_idx, arg->_idx);
                else
                  add_deferred_edge(resproj->_idx, arg->_idx);
                arg_esp->_hidden_alias = true;
              }
            }
          }
1624
          copy_dependencies = true;
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1625 1626 1627 1628
        } else {
          set_escape_state(call->_idx, PointsToNode::GlobalEscape);
          if (resproj != NULL)
            add_pointsto_edge(resproj->_idx, _phantom_object);
1629 1630 1631 1632 1633 1634 1635 1636
          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 = _nodes->adr_at(arg->_idx);
              arg_esp->_hidden_alias = true;
            }
          }
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        }
1638 1639
        if (copy_dependencies)
          call_analyzer->copy_dependencies(C()->dependencies());
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1640
      }
1641 1642
      if (done)
        _processed.set(resproj->_idx);
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      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) {
          PointsToNode *ptadr = ptnode_adr(call->_idx);
          set_escape_state(call->_idx, PointsToNode::GlobalEscape);
          if (resproj != NULL)
            add_pointsto_edge(resproj->_idx, _phantom_object);
        }
      }
1663
      _processed.set(resproj->_idx);
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1664 1665 1666 1667
    }
  }
}

1668 1669 1670 1671 1672 1673 1674 1675 1676 1677 1678 1679 1680 1681 1682 1683 1684 1685 1686 1687 1688 1689 1690 1691 1692 1693 1694 1695 1696 1697
// 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 {
      // Have to process call's arguments first.
      PointsToNode::NodeType nt = PointsToNode::UnknownType;

      // Check if a call returns an object.
      const TypeTuple *r = n->as_Call()->tf()->range();
      if (r->cnt() > TypeFunc::Parms &&
          n->as_Call()->proj_out(TypeFunc::Parms) != NULL) {
        // Note:  use isa_ptr() instead of isa_oopptr() here because
        //        the _multianewarray functions return a TypeRawPtr.
        if (r->field_at(TypeFunc::Parms)->isa_ptr() != NULL) {
          nt = PointsToNode::JavaObject;
        }
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      }
1699
      add_node(n, nt, PointsToNode::UnknownEscape, false);
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    }
1701
    return;
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1702 1703
  }

1704 1705 1706 1707 1708 1709 1710 1711 1712 1713 1714 1715 1716 1717 1718 1719 1720 1721 1722 1723 1724 1725 1726 1727 1728 1729 1730 1731 1732 1733 1734 1735 1736 1737 1738 1739 1740 1741
  // 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:
    {
      add_node(n, PointsToNode::LocalVar, PointsToNode::UnknownEscape, false);
      int ti = n->in(1)->_idx;
      PointsToNode::NodeType nt = _nodes->adr_at(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;
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1743 1744 1745 1746 1747 1748 1749 1750 1751
      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;
    }
1752 1753 1754 1755 1756 1757 1758 1759 1760 1761 1762 1763
    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;
    }
1764 1765 1766 1767 1768 1769
    case Op_LoadKlass:
    {
      add_node(n, PointsToNode::JavaObject, PointsToNode::GlobalEscape, true);
      break;
    }
    case Op_LoadP:
1770
    case Op_LoadN:
1771 1772
    {
      const Type *t = phase->type(n);
1773
      if (!t->isa_narrowoop() && t->isa_ptr() == NULL) {
1774 1775 1776 1777 1778 1779 1780 1781 1782 1783 1784 1785 1786 1787 1788 1789 1790 1791 1792 1793 1794 1795 1796 1797 1798 1799 1800 1801 1802 1803 1804 1805 1806 1807 1808 1809 1810 1811 1812 1813 1814 1815 1816 1817 1818 1819 1820 1821 1822 1823 1824 1825 1826 1827 1828 1829 1830 1831 1832 1833 1834 1835 1836 1837 1838 1839 1840 1841 1842 1843 1844 1845 1846 1847 1848 1849 1850 1851 1852 1853 1854 1855 1856 1857 1858 1859 1860 1861 1862
        _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:
    {
      if (n->as_Phi()->type()->isa_ptr() == NULL) {
        // nothing to do if not an 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 = _nodes->adr_at(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 result projection from a call
      if (n->as_Proj()->_con == TypeFunc::Parms && n->in(0)->is_Call() ) {
        add_node(n, PointsToNode::LocalVar, PointsToNode::UnknownEscape, false);
        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);
        }
      } else {
        _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 = _nodes->adr_at(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:
1863
    case Op_StoreN:
1864 1865
    {
      const Type *adr_type = phase->type(n->in(MemNode::Address));
1866 1867 1868
      if (adr_type->isa_narrowoop()) {
        adr_type = adr_type->is_narrowoop()->make_oopptr();
      }
1869 1870 1871 1872 1873 1874 1875 1876 1877 1878 1879 1880 1881 1882 1883 1884 1885 1886 1887 1888 1889
      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:
1890
    case Op_CompareAndSwapN:
1891 1892
    {
      const Type *adr_type = phase->type(n->in(MemNode::Address));
1893 1894 1895
      if (adr_type->isa_narrowoop()) {
        adr_type = adr_type->is_narrowoop()->make_oopptr();
      }
1896 1897 1898 1899 1900 1901 1902 1903 1904 1905 1906 1907 1908 1909 1910 1911 1912 1913 1914
      if (adr_type->isa_oopptr()) {
        add_node(n, PointsToNode::UnknownType, PointsToNode::UnknownEscape, false);
      } else {
        _processed.set(n->_idx);
        return;
      }
      break;
    }
    case Op_ThreadLocal:
    {
      add_node(n, PointsToNode::JavaObject, PointsToNode::ArgEscape, true);
      break;
    }
    default:
      ;
      // nothing to do
  }
  return;
}
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1916 1917 1918
void ConnectionGraph::build_connection_graph(Node *n, PhaseTransform *phase) {
  // Don't set processed bit for AddP, LoadP, StoreP since
  // they may need more then one pass to process.
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  if (_processed.test(n->_idx))
1920 1921 1922
    return; // No need to redefine node's state.

  PointsToNode *ptadr = ptnode_adr(n->_idx);
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1923 1924 1925 1926

  if (n->is_Call()) {
    CallNode *call = n->as_Call();
    process_call_arguments(call, phase);
1927
    _processed.set(n->_idx);
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1928 1929 1930
    return;
  }

1931
  switch (n->Opcode()) {
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1932 1933
    case Op_AddP:
    {
1934 1935
      Node *base = get_addp_base(n);
      // Create a field edge to this node from everything base could point to.
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1936 1937 1938 1939
      VectorSet ptset(Thread::current()->resource_area());
      PointsTo(ptset, base, phase);
      for( VectorSetI i(&ptset); i.test(); ++i ) {
        uint pt = i.elem;
1940
        add_field_edge(pt, n->_idx, address_offset(n, phase));
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1941 1942 1943
      }
      break;
    }
1944
    case Op_CastX2P:
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1945
    {
1946 1947 1948 1949 1950
      assert(false, "Op_CastX2P");
      break;
    }
    case Op_CastPP:
    case Op_CheckCastPP:
1951 1952
    case Op_EncodeP:
    case Op_DecodeN:
1953 1954 1955 1956
    {
      int ti = n->in(1)->_idx;
      if (_nodes->adr_at(ti)->node_type() == PointsToNode::JavaObject) {
        add_pointsto_edge(n->_idx, ti);
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1957
      } else {
1958
        add_deferred_edge(n->_idx, ti);
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1959 1960 1961 1962
      }
      _processed.set(n->_idx);
      break;
    }
1963
    case Op_ConP:
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1964
    {
1965
      assert(false, "Op_ConP");
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1966 1967 1968 1969
      break;
    }
    case Op_CreateEx:
    {
1970
      assert(false, "Op_CreateEx");
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1971 1972 1973 1974
      break;
    }
    case Op_LoadKlass:
    {
1975
      assert(false, "Op_LoadKlass");
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1976 1977 1978 1979 1980
      break;
    }
    case Op_LoadP:
    {
      const Type *t = phase->type(n);
1981 1982 1983 1984
#ifdef ASSERT
      if (t->isa_ptr() == NULL)
        assert(false, "Op_LoadP");
#endif
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1986
      Node* adr = n->in(MemNode::Address)->uncast();
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1987
      const Type *adr_type = phase->type(adr);
1988 1989 1990 1991 1992 1993
      Node* adr_base;
      if (adr->is_AddP()) {
        adr_base = get_addp_base(adr);
      } else {
        adr_base = adr;
      }
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1994

1995 1996
      // For everything "adr_base" could point to, create a deferred edge from
      // this node to each field with the same offset.
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1997 1998
      VectorSet ptset(Thread::current()->resource_area());
      PointsTo(ptset, adr_base, phase);
1999
      int offset = address_offset(adr, phase);
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2000 2001
      for( VectorSetI i(&ptset); i.test(); ++i ) {
        uint pt = i.elem;
2002
        add_deferred_edge_to_fields(n->_idx, pt, offset);
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2003 2004 2005
      }
      break;
    }
2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030 2031 2032 2033 2034 2035 2036 2037 2038 2039 2040 2041 2042 2043 2044 2045 2046 2047 2048 2049 2050 2051 2052 2053 2054 2055 2056 2057 2058 2059 2060 2061
    case Op_Parm:
    {
      assert(false, "Op_Parm");
      break;
    }
    case Op_Phi:
    {
#ifdef ASSERT
      if (n->as_Phi()->type()->isa_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;
        if (_nodes->adr_at(in->_idx)->node_type() == 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 result projection from a call
      if (n->as_Proj()->_con == TypeFunc::Parms && n->in(0)->is_Call() ) {
        process_call_result(n->as_Proj(), phase);
        assert(_processed.test(n->_idx), "all call results should be processed");
      } else {
        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;
      if (_nodes->adr_at(ti)->node_type() == PointsToNode::JavaObject) {
        add_pointsto_edge(n->_idx, ti);
      } else {
        add_deferred_edge(n->_idx, ti);
      }
      _processed.set(n->_idx);
      break;
    }
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2062 2063 2064 2065 2066 2067
    case Op_StoreP:
    case Op_StorePConditional:
    case Op_CompareAndSwapP:
    {
      Node *adr = n->in(MemNode::Address);
      const Type *adr_type = phase->type(adr);
2068
#ifdef ASSERT
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2069
      if (!adr_type->isa_oopptr())
2070 2071
        assert(phase->type(adr) == TypeRawPtr::NOTNULL, "Op_StoreP");
#endif
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2072

2073 2074 2075 2076 2077
      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.
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2078 2079 2080 2081
      VectorSet ptset(Thread::current()->resource_area());
      PointsTo(ptset, adr_base, phase);
      for( VectorSetI i(&ptset); i.test(); ++i ) {
        uint pt = i.elem;
2082
        add_edge_from_fields(pt, val->_idx, address_offset(adr, phase));
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2083 2084 2085
      }
      break;
    }
2086
    case Op_ThreadLocal:
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2087
    {
2088
      assert(false, "Op_ThreadLocal");
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      break;
    }
    default:
      ;
      // nothing to do
  }
}

#ifndef PRODUCT
void ConnectionGraph::dump() {
  PhaseGVN  *igvn = _compile->initial_gvn();
  bool first = true;

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

    if (ptn_type != PointsToNode::JavaObject || ptn->_node == NULL)
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      continue;
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    PointsToNode::EscapeState es = escape_state(ptn->_node, igvn);
    if (ptn->_node->is_Allocate() && (es == PointsToNode::NoEscape || Verbose)) {
      if (first) {
        tty->cr();
        tty->print("======== Connection graph for ");
        C()->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 = _nodes->adr_at(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 ) {
          tty->print("%6d  LocalVar [[%d]]", li, ni);
          _nodes->adr_at(li)->_node->dump();
        }
      }
      if (Verbose) {
        // Print all fields which reference this allocation
        for (uint i = 0; i < ptn->edge_count(); i++) {
          uint ei = ptn->edge_target(i);
          tty->print("%6d  Field [[%d]]", ei, ni);
          _nodes->adr_at(ei)->_node->dump();
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        }
      }
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      tty->cr();
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    }
  }
}
#endif