compile.cpp 130.3 KB
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/*
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 * Copyright (c) 1997, 2012, Oracle and/or its affiliates. All rights reserved.
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 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.
 *
 * This code is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 *
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 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
 * or visit www.oracle.com if you need additional information or have any
 * questions.
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 *
 */

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#include "precompiled.hpp"
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#include "asm/macroAssembler.hpp"
#include "asm/macroAssembler.inline.hpp"
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#include "classfile/systemDictionary.hpp"
#include "code/exceptionHandlerTable.hpp"
#include "code/nmethod.hpp"
#include "compiler/compileLog.hpp"
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#include "compiler/disassembler.hpp"
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#include "compiler/oopMap.hpp"
#include "opto/addnode.hpp"
#include "opto/block.hpp"
#include "opto/c2compiler.hpp"
#include "opto/callGenerator.hpp"
#include "opto/callnode.hpp"
#include "opto/cfgnode.hpp"
#include "opto/chaitin.hpp"
#include "opto/compile.hpp"
#include "opto/connode.hpp"
#include "opto/divnode.hpp"
#include "opto/escape.hpp"
#include "opto/idealGraphPrinter.hpp"
#include "opto/loopnode.hpp"
#include "opto/machnode.hpp"
#include "opto/macro.hpp"
#include "opto/matcher.hpp"
#include "opto/memnode.hpp"
#include "opto/mulnode.hpp"
#include "opto/node.hpp"
#include "opto/opcodes.hpp"
#include "opto/output.hpp"
#include "opto/parse.hpp"
#include "opto/phaseX.hpp"
#include "opto/rootnode.hpp"
#include "opto/runtime.hpp"
#include "opto/stringopts.hpp"
#include "opto/type.hpp"
#include "opto/vectornode.hpp"
#include "runtime/arguments.hpp"
#include "runtime/signature.hpp"
#include "runtime/stubRoutines.hpp"
#include "runtime/timer.hpp"
#include "utilities/copy.hpp"
#ifdef TARGET_ARCH_MODEL_x86_32
# include "adfiles/ad_x86_32.hpp"
#endif
#ifdef TARGET_ARCH_MODEL_x86_64
# include "adfiles/ad_x86_64.hpp"
#endif
#ifdef TARGET_ARCH_MODEL_sparc
# include "adfiles/ad_sparc.hpp"
#endif
#ifdef TARGET_ARCH_MODEL_zero
# include "adfiles/ad_zero.hpp"
#endif
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#ifdef TARGET_ARCH_MODEL_arm
# include "adfiles/ad_arm.hpp"
#endif
#ifdef TARGET_ARCH_MODEL_ppc
# include "adfiles/ad_ppc.hpp"
#endif
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// -------------------- Compile::mach_constant_base_node -----------------------
// Constant table base node singleton.
MachConstantBaseNode* Compile::mach_constant_base_node() {
  if (_mach_constant_base_node == NULL) {
    _mach_constant_base_node = new (C) MachConstantBaseNode();
    _mach_constant_base_node->add_req(C->root());
  }
  return _mach_constant_base_node;
}


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/// Support for intrinsics.

// Return the index at which m must be inserted (or already exists).
// The sort order is by the address of the ciMethod, with is_virtual as minor key.
int Compile::intrinsic_insertion_index(ciMethod* m, bool is_virtual) {
#ifdef ASSERT
  for (int i = 1; i < _intrinsics->length(); i++) {
    CallGenerator* cg1 = _intrinsics->at(i-1);
    CallGenerator* cg2 = _intrinsics->at(i);
    assert(cg1->method() != cg2->method()
           ? cg1->method()     < cg2->method()
           : cg1->is_virtual() < cg2->is_virtual(),
           "compiler intrinsics list must stay sorted");
  }
#endif
  // Binary search sorted list, in decreasing intervals [lo, hi].
  int lo = 0, hi = _intrinsics->length()-1;
  while (lo <= hi) {
    int mid = (uint)(hi + lo) / 2;
    ciMethod* mid_m = _intrinsics->at(mid)->method();
    if (m < mid_m) {
      hi = mid-1;
    } else if (m > mid_m) {
      lo = mid+1;
    } else {
      // look at minor sort key
      bool mid_virt = _intrinsics->at(mid)->is_virtual();
      if (is_virtual < mid_virt) {
        hi = mid-1;
      } else if (is_virtual > mid_virt) {
        lo = mid+1;
      } else {
        return mid;  // exact match
      }
    }
  }
  return lo;  // inexact match
}

void Compile::register_intrinsic(CallGenerator* cg) {
  if (_intrinsics == NULL) {
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    _intrinsics = new (comp_arena())GrowableArray<CallGenerator*>(comp_arena(), 60, 0, NULL);
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  }
  // This code is stolen from ciObjectFactory::insert.
  // Really, GrowableArray should have methods for
  // insert_at, remove_at, and binary_search.
  int len = _intrinsics->length();
  int index = intrinsic_insertion_index(cg->method(), cg->is_virtual());
  if (index == len) {
    _intrinsics->append(cg);
  } else {
#ifdef ASSERT
    CallGenerator* oldcg = _intrinsics->at(index);
    assert(oldcg->method() != cg->method() || oldcg->is_virtual() != cg->is_virtual(), "don't register twice");
#endif
    _intrinsics->append(_intrinsics->at(len-1));
    int pos;
    for (pos = len-2; pos >= index; pos--) {
      _intrinsics->at_put(pos+1,_intrinsics->at(pos));
    }
    _intrinsics->at_put(index, cg);
  }
  assert(find_intrinsic(cg->method(), cg->is_virtual()) == cg, "registration worked");
}

CallGenerator* Compile::find_intrinsic(ciMethod* m, bool is_virtual) {
  assert(m->is_loaded(), "don't try this on unloaded methods");
  if (_intrinsics != NULL) {
    int index = intrinsic_insertion_index(m, is_virtual);
    if (index < _intrinsics->length()
        && _intrinsics->at(index)->method() == m
        && _intrinsics->at(index)->is_virtual() == is_virtual) {
      return _intrinsics->at(index);
    }
  }
  // Lazily create intrinsics for intrinsic IDs well-known in the runtime.
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  if (m->intrinsic_id() != vmIntrinsics::_none &&
      m->intrinsic_id() <= vmIntrinsics::LAST_COMPILER_INLINE) {
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    CallGenerator* cg = make_vm_intrinsic(m, is_virtual);
    if (cg != NULL) {
      // Save it for next time:
      register_intrinsic(cg);
      return cg;
    } else {
      gather_intrinsic_statistics(m->intrinsic_id(), is_virtual, _intrinsic_disabled);
    }
  }
  return NULL;
}

// Compile:: register_library_intrinsics and make_vm_intrinsic are defined
// in library_call.cpp.


#ifndef PRODUCT
// statistics gathering...

juint  Compile::_intrinsic_hist_count[vmIntrinsics::ID_LIMIT] = {0};
jubyte Compile::_intrinsic_hist_flags[vmIntrinsics::ID_LIMIT] = {0};

bool Compile::gather_intrinsic_statistics(vmIntrinsics::ID id, bool is_virtual, int flags) {
  assert(id > vmIntrinsics::_none && id < vmIntrinsics::ID_LIMIT, "oob");
  int oflags = _intrinsic_hist_flags[id];
  assert(flags != 0, "what happened?");
  if (is_virtual) {
    flags |= _intrinsic_virtual;
  }
  bool changed = (flags != oflags);
  if ((flags & _intrinsic_worked) != 0) {
    juint count = (_intrinsic_hist_count[id] += 1);
    if (count == 1) {
      changed = true;           // first time
    }
    // increment the overall count also:
    _intrinsic_hist_count[vmIntrinsics::_none] += 1;
  }
  if (changed) {
    if (((oflags ^ flags) & _intrinsic_virtual) != 0) {
      // Something changed about the intrinsic's virtuality.
      if ((flags & _intrinsic_virtual) != 0) {
        // This is the first use of this intrinsic as a virtual call.
        if (oflags != 0) {
          // We already saw it as a non-virtual, so note both cases.
          flags |= _intrinsic_both;
        }
      } else if ((oflags & _intrinsic_both) == 0) {
        // This is the first use of this intrinsic as a non-virtual
        flags |= _intrinsic_both;
      }
    }
    _intrinsic_hist_flags[id] = (jubyte) (oflags | flags);
  }
  // update the overall flags also:
  _intrinsic_hist_flags[vmIntrinsics::_none] |= (jubyte) flags;
  return changed;
}

static char* format_flags(int flags, char* buf) {
  buf[0] = 0;
  if ((flags & Compile::_intrinsic_worked) != 0)    strcat(buf, ",worked");
  if ((flags & Compile::_intrinsic_failed) != 0)    strcat(buf, ",failed");
  if ((flags & Compile::_intrinsic_disabled) != 0)  strcat(buf, ",disabled");
  if ((flags & Compile::_intrinsic_virtual) != 0)   strcat(buf, ",virtual");
  if ((flags & Compile::_intrinsic_both) != 0)      strcat(buf, ",nonvirtual");
  if (buf[0] == 0)  strcat(buf, ",");
  assert(buf[0] == ',', "must be");
  return &buf[1];
}

void Compile::print_intrinsic_statistics() {
  char flagsbuf[100];
  ttyLocker ttyl;
  if (xtty != NULL)  xtty->head("statistics type='intrinsic'");
  tty->print_cr("Compiler intrinsic usage:");
  juint total = _intrinsic_hist_count[vmIntrinsics::_none];
  if (total == 0)  total = 1;  // avoid div0 in case of no successes
  #define PRINT_STAT_LINE(name, c, f) \
    tty->print_cr("  %4d (%4.1f%%) %s (%s)", (int)(c), ((c) * 100.0) / total, name, f);
  for (int index = 1 + (int)vmIntrinsics::_none; index < (int)vmIntrinsics::ID_LIMIT; index++) {
    vmIntrinsics::ID id = (vmIntrinsics::ID) index;
    int   flags = _intrinsic_hist_flags[id];
    juint count = _intrinsic_hist_count[id];
    if ((flags | count) != 0) {
      PRINT_STAT_LINE(vmIntrinsics::name_at(id), count, format_flags(flags, flagsbuf));
    }
  }
  PRINT_STAT_LINE("total", total, format_flags(_intrinsic_hist_flags[vmIntrinsics::_none], flagsbuf));
  if (xtty != NULL)  xtty->tail("statistics");
}

void Compile::print_statistics() {
  { ttyLocker ttyl;
    if (xtty != NULL)  xtty->head("statistics type='opto'");
    Parse::print_statistics();
    PhaseCCP::print_statistics();
    PhaseRegAlloc::print_statistics();
    Scheduling::print_statistics();
    PhasePeephole::print_statistics();
    PhaseIdealLoop::print_statistics();
    if (xtty != NULL)  xtty->tail("statistics");
  }
  if (_intrinsic_hist_flags[vmIntrinsics::_none] != 0) {
    // put this under its own <statistics> element.
    print_intrinsic_statistics();
  }
}
#endif //PRODUCT

// Support for bundling info
Bundle* Compile::node_bundling(const Node *n) {
  assert(valid_bundle_info(n), "oob");
  return &_node_bundling_base[n->_idx];
}

bool Compile::valid_bundle_info(const Node *n) {
  return (_node_bundling_limit > n->_idx);
}


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void Compile::gvn_replace_by(Node* n, Node* nn) {
  for (DUIterator_Last imin, i = n->last_outs(imin); i >= imin; ) {
    Node* use = n->last_out(i);
    bool is_in_table = initial_gvn()->hash_delete(use);
    uint uses_found = 0;
    for (uint j = 0; j < use->len(); j++) {
      if (use->in(j) == n) {
        if (j < use->req())
          use->set_req(j, nn);
        else
          use->set_prec(j, nn);
        uses_found++;
      }
    }
    if (is_in_table) {
      // reinsert into table
      initial_gvn()->hash_find_insert(use);
    }
    record_for_igvn(use);
    i -= uses_found;    // we deleted 1 or more copies of this edge
  }
}


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static inline bool not_a_node(const Node* n) {
  if (n == NULL)                   return true;
  if (((intptr_t)n & 1) != 0)      return true;  // uninitialized, etc.
  if (*(address*)n == badAddress)  return true;  // kill by Node::destruct
  return false;
}
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// Identify all nodes that are reachable from below, useful.
// Use breadth-first pass that records state in a Unique_Node_List,
// recursive traversal is slower.
void Compile::identify_useful_nodes(Unique_Node_List &useful) {
  int estimated_worklist_size = unique();
  useful.map( estimated_worklist_size, NULL );  // preallocate space

  // Initialize worklist
  if (root() != NULL)     { useful.push(root()); }
  // If 'top' is cached, declare it useful to preserve cached node
  if( cached_top_node() ) { useful.push(cached_top_node()); }

  // Push all useful nodes onto the list, breadthfirst
  for( uint next = 0; next < useful.size(); ++next ) {
    assert( next < unique(), "Unique useful nodes < total nodes");
    Node *n  = useful.at(next);
    uint max = n->len();
    for( uint i = 0; i < max; ++i ) {
      Node *m = n->in(i);
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      if (not_a_node(m))  continue;
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      useful.push(m);
    }
  }
}

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// Update dead_node_list with any missing dead nodes using useful
// list. Consider all non-useful nodes to be useless i.e., dead nodes.
void Compile::update_dead_node_list(Unique_Node_List &useful) {
  uint max_idx = unique();
  VectorSet& useful_node_set = useful.member_set();

  for (uint node_idx = 0; node_idx < max_idx; node_idx++) {
    // If node with index node_idx is not in useful set,
    // mark it as dead in dead node list.
    if (! useful_node_set.test(node_idx) ) {
      record_dead_node(node_idx);
    }
  }
}

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void Compile::remove_useless_late_inlines(GrowableArray<CallGenerator*>* inlines, Unique_Node_List &useful) {
  int shift = 0;
  for (int i = 0; i < inlines->length(); i++) {
    CallGenerator* cg = inlines->at(i);
    CallNode* call = cg->call_node();
    if (shift > 0) {
      inlines->at_put(i-shift, cg);
    }
    if (!useful.member(call)) {
      shift++;
    }
  }
  inlines->trunc_to(inlines->length()-shift);
}

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// Disconnect all useless nodes by disconnecting those at the boundary.
void Compile::remove_useless_nodes(Unique_Node_List &useful) {
  uint next = 0;
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  while (next < useful.size()) {
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    Node *n = useful.at(next++);
    // Use raw traversal of out edges since this code removes out edges
    int max = n->outcnt();
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    for (int j = 0; j < max; ++j) {
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      Node* child = n->raw_out(j);
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      if (! useful.member(child)) {
        assert(!child->is_top() || child != top(),
               "If top is cached in Compile object it is in useful list");
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        // Only need to remove this out-edge to the useless node
        n->raw_del_out(j);
        --j;
        --max;
      }
    }
    if (n->outcnt() == 1 && n->has_special_unique_user()) {
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      record_for_igvn(n->unique_out());
    }
  }
  // Remove useless macro and predicate opaq nodes
  for (int i = C->macro_count()-1; i >= 0; i--) {
    Node* n = C->macro_node(i);
    if (!useful.member(n)) {
      remove_macro_node(n);
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    }
  }
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  // Remove useless expensive node
  for (int i = C->expensive_count()-1; i >= 0; i--) {
    Node* n = C->expensive_node(i);
    if (!useful.member(n)) {
      remove_expensive_node(n);
    }
  }
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  // clean up the late inline lists
  remove_useless_late_inlines(&_string_late_inlines, useful);
  remove_useless_late_inlines(&_late_inlines, useful);
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  debug_only(verify_graph_edges(true/*check for no_dead_code*/);)
}

//------------------------------frame_size_in_words-----------------------------
// frame_slots in units of words
int Compile::frame_size_in_words() const {
  // shift is 0 in LP32 and 1 in LP64
  const int shift = (LogBytesPerWord - LogBytesPerInt);
  int words = _frame_slots >> shift;
  assert( words << shift == _frame_slots, "frame size must be properly aligned in LP64" );
  return words;
}

// ============================================================================
//------------------------------CompileWrapper---------------------------------
class CompileWrapper : public StackObj {
  Compile *const _compile;
 public:
  CompileWrapper(Compile* compile);

  ~CompileWrapper();
};

CompileWrapper::CompileWrapper(Compile* compile) : _compile(compile) {
  // the Compile* pointer is stored in the current ciEnv:
  ciEnv* env = compile->env();
  assert(env == ciEnv::current(), "must already be a ciEnv active");
  assert(env->compiler_data() == NULL, "compile already active?");
  env->set_compiler_data(compile);
  assert(compile == Compile::current(), "sanity");

  compile->set_type_dict(NULL);
  compile->set_type_hwm(NULL);
  compile->set_type_last_size(0);
  compile->set_last_tf(NULL, NULL);
  compile->set_indexSet_arena(NULL);
  compile->set_indexSet_free_block_list(NULL);
  compile->init_type_arena();
  Type::Initialize(compile);
  _compile->set_scratch_buffer_blob(NULL);
  _compile->begin_method();
}
CompileWrapper::~CompileWrapper() {
  _compile->end_method();
  if (_compile->scratch_buffer_blob() != NULL)
    BufferBlob::free(_compile->scratch_buffer_blob());
  _compile->env()->set_compiler_data(NULL);
}


//----------------------------print_compile_messages---------------------------
void Compile::print_compile_messages() {
#ifndef PRODUCT
  // Check if recompiling
  if (_subsume_loads == false && PrintOpto) {
    // Recompiling without allowing machine instructions to subsume loads
    tty->print_cr("*********************************************************");
    tty->print_cr("** Bailout: Recompile without subsuming loads          **");
    tty->print_cr("*********************************************************");
  }
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  if (_do_escape_analysis != DoEscapeAnalysis && PrintOpto) {
    // Recompiling without escape analysis
    tty->print_cr("*********************************************************");
    tty->print_cr("** Bailout: Recompile without escape analysis          **");
    tty->print_cr("*********************************************************");
  }
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  if (env()->break_at_compile()) {
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    // Open the debugger when compiling this method.
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    tty->print("### Breaking when compiling: ");
    method()->print_short_name();
    tty->cr();
    BREAKPOINT;
  }

  if( PrintOpto ) {
    if (is_osr_compilation()) {
      tty->print("[OSR]%3d", _compile_id);
    } else {
      tty->print("%3d", _compile_id);
    }
  }
#endif
}


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//-----------------------init_scratch_buffer_blob------------------------------
// Construct a temporary BufferBlob and cache it for this compile.
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void Compile::init_scratch_buffer_blob(int const_size) {
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  // If there is already a scratch buffer blob allocated and the
  // constant section is big enough, use it.  Otherwise free the
  // current and allocate a new one.
  BufferBlob* blob = scratch_buffer_blob();
  if ((blob != NULL) && (const_size <= _scratch_const_size)) {
    // Use the current blob.
  } else {
    if (blob != NULL) {
      BufferBlob::free(blob);
    }

    ResourceMark rm;
    _scratch_const_size = const_size;
    int size = (MAX_inst_size + MAX_stubs_size + _scratch_const_size);
    blob = BufferBlob::create("Compile::scratch_buffer", size);
    // Record the buffer blob for next time.
    set_scratch_buffer_blob(blob);
    // Have we run out of code space?
    if (scratch_buffer_blob() == NULL) {
      // Let CompilerBroker disable further compilations.
      record_failure("Not enough space for scratch buffer in CodeCache");
      return;
    }
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  }
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  // Initialize the relocation buffers
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  relocInfo* locs_buf = (relocInfo*) blob->content_end() - MAX_locs_size;
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  set_scratch_locs_memory(locs_buf);
}


//-----------------------scratch_emit_size-------------------------------------
// Helper function that computes size by emitting code
uint Compile::scratch_emit_size(const Node* n) {
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  // Start scratch_emit_size section.
  set_in_scratch_emit_size(true);

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  // Emit into a trash buffer and count bytes emitted.
  // This is a pretty expensive way to compute a size,
  // but it works well enough if seldom used.
  // All common fixed-size instructions are given a size
  // method by the AD file.
  // Note that the scratch buffer blob and locs memory are
  // allocated at the beginning of the compile task, and
  // may be shared by several calls to scratch_emit_size.
  // The allocation of the scratch buffer blob is particularly
  // expensive, since it has to grab the code cache lock.
  BufferBlob* blob = this->scratch_buffer_blob();
  assert(blob != NULL, "Initialize BufferBlob at start");
  assert(blob->size() > MAX_inst_size, "sanity");
  relocInfo* locs_buf = scratch_locs_memory();
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  address blob_begin = blob->content_begin();
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  address blob_end   = (address)locs_buf;
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  assert(blob->content_contains(blob_end), "sanity");
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  CodeBuffer buf(blob_begin, blob_end - blob_begin);
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  buf.initialize_consts_size(_scratch_const_size);
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  buf.initialize_stubs_size(MAX_stubs_size);
  assert(locs_buf != NULL, "sanity");
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  int lsize = MAX_locs_size / 3;
  buf.consts()->initialize_shared_locs(&locs_buf[lsize * 0], lsize);
  buf.insts()->initialize_shared_locs( &locs_buf[lsize * 1], lsize);
  buf.stubs()->initialize_shared_locs( &locs_buf[lsize * 2], lsize);

  // Do the emission.
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  Label fakeL; // Fake label for branch instructions.
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  Label*   saveL = NULL;
  uint save_bnum = 0;
  bool is_branch = n->is_MachBranch();
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  if (is_branch) {
    MacroAssembler masm(&buf);
    masm.bind(fakeL);
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    n->as_MachBranch()->save_label(&saveL, &save_bnum);
    n->as_MachBranch()->label_set(&fakeL, 0);
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  }
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  n->emit(buf, this->regalloc());
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  if (is_branch) // Restore label.
    n->as_MachBranch()->label_set(saveL, save_bnum);
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  // End scratch_emit_size section.
  set_in_scratch_emit_size(false);

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  return buf.insts_size();
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}


// ============================================================================
//------------------------------Compile standard-------------------------------
debug_only( int Compile::_debug_idx = 100000; )

// Compile a method.  entry_bci is -1 for normal compilations and indicates
// the continuation bci for on stack replacement.


604
Compile::Compile( ciEnv* ci_env, C2Compiler* compiler, ciMethod* target, int osr_bci, bool subsume_loads, bool do_escape_analysis )
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                : Phase(Compiler),
                  _env(ci_env),
                  _log(ci_env->log()),
                  _compile_id(ci_env->compile_id()),
                  _save_argument_registers(false),
                  _stub_name(NULL),
                  _stub_function(NULL),
                  _stub_entry_point(NULL),
                  _method(target),
                  _entry_bci(osr_bci),
                  _initial_gvn(NULL),
                  _for_igvn(NULL),
                  _warm_calls(NULL),
                  _subsume_loads(subsume_loads),
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                  _do_escape_analysis(do_escape_analysis),
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                  _failure_reason(NULL),
                  _code_buffer("Compile::Fill_buffer"),
                  _orig_pc_slot(0),
                  _orig_pc_slot_offset_in_bytes(0),
624
                  _has_method_handle_invokes(false),
625
                  _mach_constant_base_node(NULL),
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                  _node_bundling_limit(0),
                  _node_bundling_base(NULL),
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                  _java_calls(0),
                  _inner_loops(0),
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                  _scratch_const_size(-1),
                  _in_scratch_emit_size(false),
632 633
                  _dead_node_list(comp_arena()),
                  _dead_node_count(0),
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#ifndef PRODUCT
                  _trace_opto_output(TraceOptoOutput || method()->has_option("TraceOptoOutput")),
                  _printer(IdealGraphPrinter::printer()),
#endif
638
                  _congraph(NULL),
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                  _late_inlines(comp_arena(), 2, 0, NULL),
                  _string_late_inlines(comp_arena(), 2, 0, NULL),
                  _late_inlines_pos(0),
                  _number_of_mh_late_inlines(0),
                  _inlining_progress(false),
                  _inlining_incrementally(false),
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                  _print_inlining_list(NULL),
                  _print_inlining(0) {
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  C = this;

  CompileWrapper cw(this);
#ifndef PRODUCT
  if (TimeCompiler2) {
    tty->print(" ");
    target->holder()->name()->print();
    tty->print(".");
    target->print_short_name();
    tty->print("  ");
  }
  TraceTime t1("Total compilation time", &_t_totalCompilation, TimeCompiler, TimeCompiler2);
  TraceTime t2(NULL, &_t_methodCompilation, TimeCompiler, false);
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  bool print_opto_assembly = PrintOptoAssembly || _method->has_option("PrintOptoAssembly");
  if (!print_opto_assembly) {
    bool print_assembly = (PrintAssembly || _method->should_print_assembly());
    if (print_assembly && !Disassembler::can_decode()) {
      tty->print_cr("PrintAssembly request changed to PrintOptoAssembly");
      print_opto_assembly = true;
    }
  }
  set_print_assembly(print_opto_assembly);
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  set_parsed_irreducible_loop(false);
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#endif

  if (ProfileTraps) {
    // Make sure the method being compiled gets its own MDO,
    // so we can at least track the decompile_count().
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    method()->ensure_method_data();
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  }

  Init(::AliasLevel);


  print_compile_messages();

  if (UseOldInlining || PrintCompilation NOT_PRODUCT( || PrintOpto) )
    _ilt = InlineTree::build_inline_tree_root();
  else
    _ilt = NULL;

  // Even if NO memory addresses are used, MergeMem nodes must have at least 1 slice
  assert(num_alias_types() >= AliasIdxRaw, "");

#define MINIMUM_NODE_HASH  1023
  // Node list that Iterative GVN will start with
  Unique_Node_List for_igvn(comp_arena());
  set_for_igvn(&for_igvn);

  // GVN that will be run immediately on new nodes
  uint estimated_size = method()->code_size()*4+64;
  estimated_size = (estimated_size < MINIMUM_NODE_HASH ? MINIMUM_NODE_HASH : estimated_size);
  PhaseGVN gvn(node_arena(), estimated_size);
  set_initial_gvn(&gvn);

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  if (PrintInlining  || PrintIntrinsics NOT_PRODUCT( || PrintOptoInlining)) {
703 704
    _print_inlining_list = new (comp_arena())GrowableArray<PrintInliningBuffer>(comp_arena(), 1, 1, PrintInliningBuffer());
  }
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  { // Scope for timing the parser
    TracePhase t3("parse", &_t_parser, true);

    // Put top into the hash table ASAP.
    initial_gvn()->transform_no_reclaim(top());

    // Set up tf(), start(), and find a CallGenerator.
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    CallGenerator* cg = NULL;
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    if (is_osr_compilation()) {
      const TypeTuple *domain = StartOSRNode::osr_domain();
      const TypeTuple *range = TypeTuple::make_range(method()->signature());
      init_tf(TypeFunc::make(domain, range));
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      StartNode* s = new (this) StartOSRNode(root(), domain);
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      initial_gvn()->set_type_bottom(s);
      init_start(s);
      cg = CallGenerator::for_osr(method(), entry_bci());
    } else {
      // Normal case.
      init_tf(TypeFunc::make(method()));
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      StartNode* s = new (this) StartNode(root(), tf()->domain());
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      initial_gvn()->set_type_bottom(s);
      init_start(s);
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      if (method()->intrinsic_id() == vmIntrinsics::_Reference_get && UseG1GC) {
        // With java.lang.ref.reference.get() we must go through the
        // intrinsic when G1 is enabled - even when get() is the root
        // method of the compile - so that, if necessary, the value in
        // the referent field of the reference object gets recorded by
        // the pre-barrier code.
        // Specifically, if G1 is enabled, the value in the referent
        // field is recorded by the G1 SATB pre barrier. This will
        // result in the referent being marked live and the reference
        // object removed from the list of discovered references during
        // reference processing.
        cg = find_intrinsic(method(), false);
      }
      if (cg == NULL) {
        float past_uses = method()->interpreter_invocation_count();
        float expected_uses = past_uses;
        cg = CallGenerator::for_inline(method(), expected_uses);
      }
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    }
    if (failing())  return;
    if (cg == NULL) {
      record_method_not_compilable_all_tiers("cannot parse method");
      return;
    }
    JVMState* jvms = build_start_state(start(), tf());
    if ((jvms = cg->generate(jvms)) == NULL) {
      record_method_not_compilable("method parse failed");
      return;
    }
    GraphKit kit(jvms);

    if (!kit.stopped()) {
      // Accept return values, and transfer control we know not where.
      // This is done by a special, unique ReturnNode bound to root.
      return_values(kit.jvms());
    }

    if (kit.has_exceptions()) {
      // Any exceptions that escape from this call must be rethrown
      // to whatever caller is dynamically above us on the stack.
      // This is done by a special, unique RethrowNode bound to root.
      rethrow_exceptions(kit.transfer_exceptions_into_jvms());
    }

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    assert(IncrementalInline || (_late_inlines.length() == 0 && !has_mh_late_inlines()), "incremental inlining is off");
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    if (_late_inlines.length() == 0 && !has_mh_late_inlines() && !failing() && has_stringbuilder()) {
      inline_string_calls(true);
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    }
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    if (failing())  return;
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    print_method("Before RemoveUseless", 3);
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    // Remove clutter produced by parsing.
    if (!failing()) {
      ResourceMark rm;
      PhaseRemoveUseless pru(initial_gvn(), &for_igvn);
    }
  }

  // Note:  Large methods are capped off in do_one_bytecode().
  if (failing())  return;

  // After parsing, node notes are no longer automagic.
  // They must be propagated by register_new_node_with_optimizer(),
  // clone(), or the like.
  set_default_node_notes(NULL);

  for (;;) {
    int successes = Inline_Warm();
    if (failing())  return;
    if (successes == 0)  break;
  }

  // Drain the list.
  Finish_Warm();
#ifndef PRODUCT
  if (_printer) {
    _printer->print_inlining(this);
  }
#endif

  if (failing())  return;
  NOT_PRODUCT( verify_graph_edges(); )

  // Now optimize
  Optimize();
  if (failing())  return;
  NOT_PRODUCT( verify_graph_edges(); )

#ifndef PRODUCT
  if (PrintIdeal) {
    ttyLocker ttyl;  // keep the following output all in one block
    // This output goes directly to the tty, not the compiler log.
    // To enable tools to match it up with the compilation activity,
    // be sure to tag this tty output with the compile ID.
    if (xtty != NULL) {
      xtty->head("ideal compile_id='%d'%s", compile_id(),
                 is_osr_compilation()    ? " compile_kind='osr'" :
                 "");
    }
    root()->dump(9999);
    if (xtty != NULL) {
      xtty->tail("ideal");
    }
  }
#endif

  // Now that we know the size of all the monitors we can add a fixed slot
  // for the original deopt pc.

  _orig_pc_slot =  fixed_slots();
  int next_slot = _orig_pc_slot + (sizeof(address) / VMRegImpl::stack_slot_size);
  set_fixed_slots(next_slot);

  // Now generate code
  Code_Gen();
  if (failing())  return;

  // Check if we want to skip execution of all compiled code.
  {
#ifndef PRODUCT
    if (OptoNoExecute) {
      record_method_not_compilable("+OptoNoExecute");  // Flag as failed
      return;
    }
    TracePhase t2("install_code", &_t_registerMethod, TimeCompiler);
#endif

    if (is_osr_compilation()) {
      _code_offsets.set_value(CodeOffsets::Verified_Entry, 0);
      _code_offsets.set_value(CodeOffsets::OSR_Entry, _first_block_size);
    } else {
      _code_offsets.set_value(CodeOffsets::Verified_Entry, _first_block_size);
      _code_offsets.set_value(CodeOffsets::OSR_Entry, 0);
    }

    env()->register_method(_method, _entry_bci,
                           &_code_offsets,
                           _orig_pc_slot_offset_in_bytes,
                           code_buffer(),
                           frame_size_in_words(), _oop_map_set,
                           &_handler_table, &_inc_table,
                           compiler,
                           env()->comp_level(),
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                           has_unsafe_access(),
                           SharedRuntime::is_wide_vector(max_vector_size())
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                           );
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    if (log() != NULL) // Print code cache state into compiler log
      log()->code_cache_state();
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  }
}

//------------------------------Compile----------------------------------------
// Compile a runtime stub
Compile::Compile( ciEnv* ci_env,
                  TypeFunc_generator generator,
                  address stub_function,
                  const char *stub_name,
                  int is_fancy_jump,
                  bool pass_tls,
                  bool save_arg_registers,
                  bool return_pc )
  : Phase(Compiler),
    _env(ci_env),
    _log(ci_env->log()),
895
    _compile_id(0),
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    _save_argument_registers(save_arg_registers),
    _method(NULL),
    _stub_name(stub_name),
    _stub_function(stub_function),
    _stub_entry_point(NULL),
    _entry_bci(InvocationEntryBci),
    _initial_gvn(NULL),
    _for_igvn(NULL),
    _warm_calls(NULL),
    _orig_pc_slot(0),
    _orig_pc_slot_offset_in_bytes(0),
    _subsume_loads(true),
908
    _do_escape_analysis(false),
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    _failure_reason(NULL),
    _code_buffer("Compile::Fill_buffer"),
911
    _has_method_handle_invokes(false),
912
    _mach_constant_base_node(NULL),
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    _node_bundling_limit(0),
    _node_bundling_base(NULL),
915 916
    _java_calls(0),
    _inner_loops(0),
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#ifndef PRODUCT
    _trace_opto_output(TraceOptoOutput),
    _printer(NULL),
#endif
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    _dead_node_list(comp_arena()),
    _dead_node_count(0),
923
    _congraph(NULL),
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    _number_of_mh_late_inlines(0),
    _inlining_progress(false),
    _inlining_incrementally(false),
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    _print_inlining_list(NULL),
    _print_inlining(0) {
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  C = this;

#ifndef PRODUCT
  TraceTime t1(NULL, &_t_totalCompilation, TimeCompiler, false);
  TraceTime t2(NULL, &_t_stubCompilation, TimeCompiler, false);
  set_print_assembly(PrintFrameConverterAssembly);
935
  set_parsed_irreducible_loop(false);
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#endif
  CompileWrapper cw(this);
  Init(/*AliasLevel=*/ 0);
  init_tf((*generator)());

  {
    // The following is a dummy for the sake of GraphKit::gen_stub
    Unique_Node_List for_igvn(comp_arena());
    set_for_igvn(&for_igvn);  // not used, but some GraphKit guys push on this
    PhaseGVN gvn(Thread::current()->resource_area(),255);
    set_initial_gvn(&gvn);    // not significant, but GraphKit guys use it pervasively
    gvn.transform_no_reclaim(top());

    GraphKit kit;
    kit.gen_stub(stub_function, stub_name, is_fancy_jump, pass_tls, return_pc);
  }

  NOT_PRODUCT( verify_graph_edges(); )
  Code_Gen();
  if (failing())  return;


  // Entry point will be accessed using compile->stub_entry_point();
  if (code_buffer() == NULL) {
    Matcher::soft_match_failure();
  } else {
    if (PrintAssembly && (WizardMode || Verbose))
      tty->print_cr("### Stub::%s", stub_name);

    if (!failing()) {
      assert(_fixed_slots == 0, "no fixed slots used for runtime stubs");

      // Make the NMethod
      // For now we mark the frame as never safe for profile stackwalking
      RuntimeStub *rs = RuntimeStub::new_runtime_stub(stub_name,
                                                      code_buffer(),
                                                      CodeOffsets::frame_never_safe,
                                                      // _code_offsets.value(CodeOffsets::Frame_Complete),
                                                      frame_size_in_words(),
                                                      _oop_map_set,
                                                      save_arg_registers);
      assert(rs != NULL && rs->is_runtime_stub(), "sanity check");

      _stub_entry_point = rs->entry_point();
    }
  }
}

//------------------------------Init-------------------------------------------
// Prepare for a single compilation
void Compile::Init(int aliaslevel) {
  _unique  = 0;
  _regalloc = NULL;

  _tf      = NULL;  // filled in later
  _top     = NULL;  // cached later
  _matcher = NULL;  // filled in later
  _cfg     = NULL;  // filled in later

  set_24_bit_selection_and_mode(Use24BitFP, false);

  _node_note_array = NULL;
  _default_node_notes = NULL;

  _immutable_memory = NULL; // filled in at first inquiry

  // Globally visible Nodes
  // First set TOP to NULL to give safe behavior during creation of RootNode
  set_cached_top_node(NULL);
1005
  set_root(new (this) RootNode());
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  // Now that you have a Root to point to, create the real TOP
1007
  set_cached_top_node( new (this) ConNode(Type::TOP) );
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  set_recent_alloc(NULL, NULL);

  // Create Debug Information Recorder to record scopes, oopmaps, etc.
1011
  env()->set_oop_recorder(new OopRecorder(env()->arena()));
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  env()->set_debug_info(new DebugInformationRecorder(env()->oop_recorder()));
  env()->set_dependencies(new Dependencies(env()));

  _fixed_slots = 0;
  set_has_split_ifs(false);
  set_has_loops(has_method() && method()->has_loops()); // first approximation
1018
  set_has_stringbuilder(false);
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  _trap_can_recompile = false;  // no traps emitted yet
  _major_progress = true; // start out assuming good things will happen
  set_has_unsafe_access(false);
1022
  set_max_vector_size(0);
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  Copy::zero_to_bytes(_trap_hist, sizeof(_trap_hist));
  set_decompile_count(0);

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  set_do_freq_based_layout(BlockLayoutByFrequency || method_has_option("BlockLayoutByFrequency"));
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  set_num_loop_opts(LoopOptsCount);
  set_do_inlining(Inline);
  set_max_inline_size(MaxInlineSize);
  set_freq_inline_size(FreqInlineSize);
  set_do_scheduling(OptoScheduling);
  set_do_count_invocations(false);
  set_do_method_data_update(false);
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  if (debug_info()->recording_non_safepoints()) {
    set_node_note_array(new(comp_arena()) GrowableArray<Node_Notes*>
                        (comp_arena(), 8, 0, NULL));
    set_default_node_notes(Node_Notes::make(this));
  }

  // // -- Initialize types before each compile --
  // // Update cached type information
  // if( _method && _method->constants() )
  //   Type::update_loaded_types(_method, _method->constants());

  // Init alias_type map.
1047
  if (!_do_escape_analysis && aliaslevel == 3)
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    aliaslevel = 2;  // No unique types without escape analysis
  _AliasLevel = aliaslevel;
  const int grow_ats = 16;
  _max_alias_types = grow_ats;
  _alias_types   = NEW_ARENA_ARRAY(comp_arena(), AliasType*, grow_ats);
  AliasType* ats = NEW_ARENA_ARRAY(comp_arena(), AliasType,  grow_ats);
  Copy::zero_to_bytes(ats, sizeof(AliasType)*grow_ats);
  {
    for (int i = 0; i < grow_ats; i++)  _alias_types[i] = &ats[i];
  }
  // Initialize the first few types.
  _alias_types[AliasIdxTop]->Init(AliasIdxTop, NULL);
  _alias_types[AliasIdxBot]->Init(AliasIdxBot, TypePtr::BOTTOM);
  _alias_types[AliasIdxRaw]->Init(AliasIdxRaw, TypeRawPtr::BOTTOM);
  _num_alias_types = AliasIdxRaw+1;
  // Zero out the alias type cache.
  Copy::zero_to_bytes(_alias_cache, sizeof(_alias_cache));
  // A NULL adr_type hits in the cache right away.  Preload the right answer.
  probe_alias_cache(NULL)->_index = AliasIdxTop;

  _intrinsics = NULL;
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  _macro_nodes = new(comp_arena()) GrowableArray<Node*>(comp_arena(), 8,  0, NULL);
  _predicate_opaqs = new(comp_arena()) GrowableArray<Node*>(comp_arena(), 8,  0, NULL);
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  _expensive_nodes = new(comp_arena()) GrowableArray<Node*>(comp_arena(), 8,  0, NULL);
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  register_library_intrinsics();
}

//---------------------------init_start----------------------------------------
// Install the StartNode on this compile object.
void Compile::init_start(StartNode* s) {
  if (failing())
    return; // already failing
  assert(s == start(), "");
}

StartNode* Compile::start() const {
  assert(!failing(), "");
  for (DUIterator_Fast imax, i = root()->fast_outs(imax); i < imax; i++) {
    Node* start = root()->fast_out(i);
    if( start->is_Start() )
      return start->as_Start();
  }
  ShouldNotReachHere();
  return NULL;
}

//-------------------------------immutable_memory-------------------------------------
// Access immutable memory
Node* Compile::immutable_memory() {
  if (_immutable_memory != NULL) {
    return _immutable_memory;
  }
  StartNode* s = start();
  for (DUIterator_Fast imax, i = s->fast_outs(imax); true; i++) {
    Node *p = s->fast_out(i);
    if (p != s && p->as_Proj()->_con == TypeFunc::Memory) {
      _immutable_memory = p;
      return _immutable_memory;
    }
  }
  ShouldNotReachHere();
  return NULL;
}

//----------------------set_cached_top_node------------------------------------
// Install the cached top node, and make sure Node::is_top works correctly.
void Compile::set_cached_top_node(Node* tn) {
  if (tn != NULL)  verify_top(tn);
  Node* old_top = _top;
  _top = tn;
  // Calling Node::setup_is_top allows the nodes the chance to adjust
  // their _out arrays.
  if (_top != NULL)     _top->setup_is_top();
  if (old_top != NULL)  old_top->setup_is_top();
  assert(_top == NULL || top()->is_top(), "");
}

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#ifdef ASSERT
uint Compile::count_live_nodes_by_graph_walk() {
  Unique_Node_List useful(comp_arena());
  // Get useful node list by walking the graph.
  identify_useful_nodes(useful);
  return useful.size();
}

void Compile::print_missing_nodes() {

  // Return if CompileLog is NULL and PrintIdealNodeCount is false.
  if ((_log == NULL) && (! PrintIdealNodeCount)) {
    return;
  }

  // This is an expensive function. It is executed only when the user
  // specifies VerifyIdealNodeCount option or otherwise knows the
  // additional work that needs to be done to identify reachable nodes
  // by walking the flow graph and find the missing ones using
  // _dead_node_list.

  Unique_Node_List useful(comp_arena());
  // Get useful node list by walking the graph.
  identify_useful_nodes(useful);

  uint l_nodes = C->live_nodes();
  uint l_nodes_by_walk = useful.size();

  if (l_nodes != l_nodes_by_walk) {
    if (_log != NULL) {
      _log->begin_head("mismatched_nodes count='%d'", abs((int) (l_nodes - l_nodes_by_walk)));
      _log->stamp();
      _log->end_head();
    }
    VectorSet& useful_member_set = useful.member_set();
    int last_idx = l_nodes_by_walk;
    for (int i = 0; i < last_idx; i++) {
      if (useful_member_set.test(i)) {
        if (_dead_node_list.test(i)) {
          if (_log != NULL) {
            _log->elem("mismatched_node_info node_idx='%d' type='both live and dead'", i);
          }
          if (PrintIdealNodeCount) {
            // Print the log message to tty
              tty->print_cr("mismatched_node idx='%d' both live and dead'", i);
              useful.at(i)->dump();
          }
        }
      }
      else if (! _dead_node_list.test(i)) {
        if (_log != NULL) {
          _log->elem("mismatched_node_info node_idx='%d' type='neither live nor dead'", i);
        }
        if (PrintIdealNodeCount) {
          // Print the log message to tty
          tty->print_cr("mismatched_node idx='%d' type='neither live nor dead'", i);
        }
      }
    }
    if (_log != NULL) {
      _log->tail("mismatched_nodes");
    }
  }
}
#endif

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#ifndef PRODUCT
void Compile::verify_top(Node* tn) const {
  if (tn != NULL) {
    assert(tn->is_Con(), "top node must be a constant");
    assert(((ConNode*)tn)->type() == Type::TOP, "top node must have correct type");
    assert(tn->in(0) != NULL, "must have live top node");
  }
}
#endif


///-------------------Managing Per-Node Debug & Profile Info-------------------

void Compile::grow_node_notes(GrowableArray<Node_Notes*>* arr, int grow_by) {
  guarantee(arr != NULL, "");
  int num_blocks = arr->length();
  if (grow_by < num_blocks)  grow_by = num_blocks;
  int num_notes = grow_by * _node_notes_block_size;
  Node_Notes* notes = NEW_ARENA_ARRAY(node_arena(), Node_Notes, num_notes);
  Copy::zero_to_bytes(notes, num_notes * sizeof(Node_Notes));
  while (num_notes > 0) {
    arr->append(notes);
    notes     += _node_notes_block_size;
    num_notes -= _node_notes_block_size;
  }
  assert(num_notes == 0, "exact multiple, please");
}

bool Compile::copy_node_notes_to(Node* dest, Node* source) {
  if (source == NULL || dest == NULL)  return false;

  if (dest->is_Con())
    return false;               // Do not push debug info onto constants.

#ifdef ASSERT
  // Leave a bread crumb trail pointing to the original node:
  if (dest != NULL && dest != source && dest->debug_orig() == NULL) {
    dest->set_debug_orig(source);
  }
#endif

  if (node_note_array() == NULL)
    return false;               // Not collecting any notes now.

  // This is a copy onto a pre-existing node, which may already have notes.
  // If both nodes have notes, do not overwrite any pre-existing notes.
  Node_Notes* source_notes = node_notes_at(source->_idx);
  if (source_notes == NULL || source_notes->is_clear())  return false;
  Node_Notes* dest_notes   = node_notes_at(dest->_idx);
  if (dest_notes == NULL || dest_notes->is_clear()) {
    return set_node_notes_at(dest->_idx, source_notes);
  }

  Node_Notes merged_notes = (*source_notes);
  // The order of operations here ensures that dest notes will win...
  merged_notes.update_from(dest_notes);
  return set_node_notes_at(dest->_idx, &merged_notes);
}


//--------------------------allow_range_check_smearing-------------------------
// Gating condition for coalescing similar range checks.
// Sometimes we try 'speculatively' replacing a series of a range checks by a
// single covering check that is at least as strong as any of them.
// If the optimization succeeds, the simplified (strengthened) range check
// will always succeed.  If it fails, we will deopt, and then give up
// on the optimization.
bool Compile::allow_range_check_smearing() const {
  // If this method has already thrown a range-check,
  // assume it was because we already tried range smearing
  // and it failed.
  uint already_trapped = trap_count(Deoptimization::Reason_range_check);
  return !already_trapped;
}


//------------------------------flatten_alias_type-----------------------------
const TypePtr *Compile::flatten_alias_type( const TypePtr *tj ) const {
  int offset = tj->offset();
  TypePtr::PTR ptr = tj->ptr();

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  // Known instance (scalarizable allocation) alias only with itself.
  bool is_known_inst = tj->isa_oopptr() != NULL &&
                       tj->is_oopptr()->is_known_instance();

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  // Process weird unsafe references.
  if (offset == Type::OffsetBot && (tj->isa_instptr() /*|| tj->isa_klassptr()*/)) {
    assert(InlineUnsafeOps, "indeterminate pointers come only from unsafe ops");
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    assert(!is_known_inst, "scalarizable allocation should not have unsafe references");
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    tj = TypeOopPtr::BOTTOM;
    ptr = tj->ptr();
    offset = tj->offset();
  }

  // Array pointers need some flattening
  const TypeAryPtr *ta = tj->isa_aryptr();
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  if( ta && is_known_inst ) {
    if ( offset != Type::OffsetBot &&
         offset > arrayOopDesc::length_offset_in_bytes() ) {
      offset = Type::OffsetBot; // Flatten constant access into array body only
      tj = ta = TypeAryPtr::make(ptr, ta->ary(), ta->klass(), true, offset, ta->instance_id());
    }
  } else if( ta && _AliasLevel >= 2 ) {
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    // For arrays indexed by constant indices, we flatten the alias
    // space to include all of the array body.  Only the header, klass
    // and array length can be accessed un-aliased.
    if( offset != Type::OffsetBot ) {
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      if( ta->const_oop() ) { // MethodData* or Method*
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        offset = Type::OffsetBot;   // Flatten constant access into array body
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        tj = ta = TypeAryPtr::make(ptr,ta->const_oop(),ta->ary(),ta->klass(),false,offset);
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      } else if( offset == arrayOopDesc::length_offset_in_bytes() ) {
        // range is OK as-is.
        tj = ta = TypeAryPtr::RANGE;
      } else if( offset == oopDesc::klass_offset_in_bytes() ) {
        tj = TypeInstPtr::KLASS; // all klass loads look alike
        ta = TypeAryPtr::RANGE; // generic ignored junk
        ptr = TypePtr::BotPTR;
      } else if( offset == oopDesc::mark_offset_in_bytes() ) {
        tj = TypeInstPtr::MARK;
        ta = TypeAryPtr::RANGE; // generic ignored junk
        ptr = TypePtr::BotPTR;
      } else {                  // Random constant offset into array body
        offset = Type::OffsetBot;   // Flatten constant access into array body
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        tj = ta = TypeAryPtr::make(ptr,ta->ary(),ta->klass(),false,offset);
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      }
    }
    // Arrays of fixed size alias with arrays of unknown size.
    if (ta->size() != TypeInt::POS) {
      const TypeAry *tary = TypeAry::make(ta->elem(), TypeInt::POS);
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      tj = ta = TypeAryPtr::make(ptr,ta->const_oop(),tary,ta->klass(),false,offset);
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    }
    // Arrays of known objects become arrays of unknown objects.
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    if (ta->elem()->isa_narrowoop() && ta->elem() != TypeNarrowOop::BOTTOM) {
      const TypeAry *tary = TypeAry::make(TypeNarrowOop::BOTTOM, ta->size());
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      tj = ta = TypeAryPtr::make(ptr,ta->const_oop(),tary,NULL,false,offset);
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    }
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    if (ta->elem()->isa_oopptr() && ta->elem() != TypeInstPtr::BOTTOM) {
      const TypeAry *tary = TypeAry::make(TypeInstPtr::BOTTOM, ta->size());
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      tj = ta = TypeAryPtr::make(ptr,ta->const_oop(),tary,NULL,false,offset);
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    }
    // Arrays of bytes and of booleans both use 'bastore' and 'baload' so
    // cannot be distinguished by bytecode alone.
    if (ta->elem() == TypeInt::BOOL) {
      const TypeAry *tary = TypeAry::make(TypeInt::BYTE, ta->size());
      ciKlass* aklass = ciTypeArrayKlass::make(T_BYTE);
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      tj = ta = TypeAryPtr::make(ptr,ta->const_oop(),tary,aklass,false,offset);
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    }
    // During the 2nd round of IterGVN, NotNull castings are removed.
    // Make sure the Bottom and NotNull variants alias the same.
    // Also, make sure exact and non-exact variants alias the same.
    if( ptr == TypePtr::NotNull || ta->klass_is_exact() ) {
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      tj = ta = TypeAryPtr::make(TypePtr::BotPTR,ta->ary(),ta->klass(),false,offset);
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    }
  }

  // Oop pointers need some flattening
  const TypeInstPtr *to = tj->isa_instptr();
  if( to && _AliasLevel >= 2 && to != TypeOopPtr::BOTTOM ) {
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    ciInstanceKlass *k = to->klass()->as_instance_klass();
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    if( ptr == TypePtr::Constant ) {
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      if (to->klass() != ciEnv::current()->Class_klass() ||
          offset < k->size_helper() * wordSize) {
        // No constant oop pointers (such as Strings); they alias with
        // unknown strings.
        assert(!is_known_inst, "not scalarizable allocation");
        tj = to = TypeInstPtr::make(TypePtr::BotPTR,to->klass(),false,0,offset);
      }
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    } else if( is_known_inst ) {
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      tj = to; // Keep NotNull and klass_is_exact for instance type
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    } else if( ptr == TypePtr::NotNull || to->klass_is_exact() ) {
      // During the 2nd round of IterGVN, NotNull castings are removed.
      // Make sure the Bottom and NotNull variants alias the same.
      // Also, make sure exact and non-exact variants alias the same.
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      tj = to = TypeInstPtr::make(TypePtr::BotPTR,to->klass(),false,0,offset);
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    }
    // Canonicalize the holder of this field
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    if (offset >= 0 && offset < instanceOopDesc::base_offset_in_bytes()) {
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      // First handle header references such as a LoadKlassNode, even if the
      // object's klass is unloaded at compile time (4965979).
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      if (!is_known_inst) { // Do it only for non-instance types
        tj = to = TypeInstPtr::make(TypePtr::BotPTR, env()->Object_klass(), false, NULL, offset);
      }
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    } else if (offset < 0 || offset >= k->size_helper() * wordSize) {
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      // Static fields are in the space above the normal instance
      // fields in the java.lang.Class instance.
      if (to->klass() != ciEnv::current()->Class_klass()) {
        to = NULL;
        tj = TypeOopPtr::BOTTOM;
        offset = tj->offset();
      }
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    } else {
      ciInstanceKlass *canonical_holder = k->get_canonical_holder(offset);
      if (!k->equals(canonical_holder) || tj->offset() != offset) {
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        if( is_known_inst ) {
          tj = to = TypeInstPtr::make(to->ptr(), canonical_holder, true, NULL, offset, to->instance_id());
        } else {
          tj = to = TypeInstPtr::make(to->ptr(), canonical_holder, false, NULL, offset);
        }
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      }
    }
  }

  // Klass pointers to object array klasses need some flattening
  const TypeKlassPtr *tk = tj->isa_klassptr();
  if( tk ) {
    // If we are referencing a field within a Klass, we need
    // to assume the worst case of an Object.  Both exact and
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    // inexact types must flatten to the same alias class so
    // use NotNull as the PTR.
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    if ( offset == Type::OffsetBot || (offset >= 0 && (size_t)offset < sizeof(Klass)) ) {

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      tj = tk = TypeKlassPtr::make(TypePtr::NotNull,
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                                   TypeKlassPtr::OBJECT->klass(),
                                   offset);
    }

    ciKlass* klass = tk->klass();
    if( klass->is_obj_array_klass() ) {
      ciKlass* k = TypeAryPtr::OOPS->klass();
      if( !k || !k->is_loaded() )                  // Only fails for some -Xcomp runs
        k = TypeInstPtr::BOTTOM->klass();
      tj = tk = TypeKlassPtr::make( TypePtr::NotNull, k, offset );
    }

    // Check for precise loads from the primary supertype array and force them
    // to the supertype cache alias index.  Check for generic array loads from
    // the primary supertype array and also force them to the supertype cache
    // alias index.  Since the same load can reach both, we need to merge
    // these 2 disparate memories into the same alias class.  Since the
    // primary supertype array is read-only, there's no chance of confusion
    // where we bypass an array load and an array store.
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    int primary_supers_offset = in_bytes(Klass::primary_supers_offset());
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    if (offset == Type::OffsetBot ||
        (offset >= primary_supers_offset &&
         offset < (int)(primary_supers_offset + Klass::primary_super_limit() * wordSize)) ||
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        offset == (int)in_bytes(Klass::secondary_super_cache_offset())) {
      offset = in_bytes(Klass::secondary_super_cache_offset());
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      tj = tk = TypeKlassPtr::make( TypePtr::NotNull, tk->klass(), offset );
    }
  }

  // Flatten all Raw pointers together.
  if (tj->base() == Type::RawPtr)
    tj = TypeRawPtr::BOTTOM;

  if (tj->base() == Type::AnyPtr)
    tj = TypePtr::BOTTOM;      // An error, which the caller must check for.

  // Flatten all to bottom for now
  switch( _AliasLevel ) {
  case 0:
    tj = TypePtr::BOTTOM;
    break;
  case 1:                       // Flatten to: oop, static, field or array
    switch (tj->base()) {
    //case Type::AryPtr: tj = TypeAryPtr::RANGE;    break;
    case Type::RawPtr:   tj = TypeRawPtr::BOTTOM;   break;
    case Type::AryPtr:   // do not distinguish arrays at all
    case Type::InstPtr:  tj = TypeInstPtr::BOTTOM;  break;
    case Type::KlassPtr: tj = TypeKlassPtr::OBJECT; break;
    case Type::AnyPtr:   tj = TypePtr::BOTTOM;      break;  // caller checks it
    default: ShouldNotReachHere();
    }
    break;
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  case 2:                       // No collapsing at level 2; keep all splits
  case 3:                       // No collapsing at level 3; keep all splits
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    break;
  default:
    Unimplemented();
  }

  offset = tj->offset();
  assert( offset != Type::OffsetTop, "Offset has fallen from constant" );

  assert( (offset != Type::OffsetBot && tj->base() != Type::AryPtr) ||
          (offset == Type::OffsetBot && tj->base() == Type::AryPtr) ||
          (offset == Type::OffsetBot && tj == TypeOopPtr::BOTTOM) ||
          (offset == Type::OffsetBot && tj == TypePtr::BOTTOM) ||
          (offset == oopDesc::mark_offset_in_bytes() && tj->base() == Type::AryPtr) ||
          (offset == oopDesc::klass_offset_in_bytes() && tj->base() == Type::AryPtr) ||
          (offset == arrayOopDesc::length_offset_in_bytes() && tj->base() == Type::AryPtr)  ,
          "For oops, klasses, raw offset must be constant; for arrays the offset is never known" );
  assert( tj->ptr() != TypePtr::TopPTR &&
          tj->ptr() != TypePtr::AnyNull &&
          tj->ptr() != TypePtr::Null, "No imprecise addresses" );
//    assert( tj->ptr() != TypePtr::Constant ||
//            tj->base() == Type::RawPtr ||
//            tj->base() == Type::KlassPtr, "No constant oop addresses" );

  return tj;
}

void Compile::AliasType::Init(int i, const TypePtr* at) {
  _index = i;
  _adr_type = at;
  _field = NULL;
  _is_rewritable = true; // default
  const TypeOopPtr *atoop = (at != NULL) ? at->isa_oopptr() : NULL;
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  if (atoop != NULL && atoop->is_known_instance()) {
    const TypeOopPtr *gt = atoop->cast_to_instance_id(TypeOopPtr::InstanceBot);
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    _general_index = Compile::current()->get_alias_index(gt);
  } else {
    _general_index = 0;
  }
}

//---------------------------------print_on------------------------------------
#ifndef PRODUCT
void Compile::AliasType::print_on(outputStream* st) {
  if (index() < 10)
        st->print("@ <%d> ", index());
  else  st->print("@ <%d>",  index());
  st->print(is_rewritable() ? "   " : " RO");
  int offset = adr_type()->offset();
  if (offset == Type::OffsetBot)
        st->print(" +any");
  else  st->print(" +%-3d", offset);
  st->print(" in ");
  adr_type()->dump_on(st);
  const TypeOopPtr* tjp = adr_type()->isa_oopptr();
  if (field() != NULL && tjp) {
    if (tjp->klass()  != field()->holder() ||
        tjp->offset() != field()->offset_in_bytes()) {
      st->print(" != ");
      field()->print();
      st->print(" ***");
    }
  }
}

void print_alias_types() {
  Compile* C = Compile::current();
  tty->print_cr("--- Alias types, AliasIdxBot .. %d", C->num_alias_types()-1);
  for (int idx = Compile::AliasIdxBot; idx < C->num_alias_types(); idx++) {
    C->alias_type(idx)->print_on(tty);
    tty->cr();
  }
}
#endif


//----------------------------probe_alias_cache--------------------------------
Compile::AliasCacheEntry* Compile::probe_alias_cache(const TypePtr* adr_type) {
  intptr_t key = (intptr_t) adr_type;
  key ^= key >> logAliasCacheSize;
  return &_alias_cache[key & right_n_bits(logAliasCacheSize)];
}


//-----------------------------grow_alias_types--------------------------------
void Compile::grow_alias_types() {
  const int old_ats  = _max_alias_types; // how many before?
  const int new_ats  = old_ats;          // how many more?
  const int grow_ats = old_ats+new_ats;  // how many now?
  _max_alias_types = grow_ats;
  _alias_types =  REALLOC_ARENA_ARRAY(comp_arena(), AliasType*, _alias_types, old_ats, grow_ats);
  AliasType* ats =    NEW_ARENA_ARRAY(comp_arena(), AliasType, new_ats);
  Copy::zero_to_bytes(ats, sizeof(AliasType)*new_ats);
  for (int i = 0; i < new_ats; i++)  _alias_types[old_ats+i] = &ats[i];
}


//--------------------------------find_alias_type------------------------------
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Compile::AliasType* Compile::find_alias_type(const TypePtr* adr_type, bool no_create, ciField* original_field) {
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  if (_AliasLevel == 0)
    return alias_type(AliasIdxBot);

  AliasCacheEntry* ace = probe_alias_cache(adr_type);
  if (ace->_adr_type == adr_type) {
    return alias_type(ace->_index);
  }

  // Handle special cases.
  if (adr_type == NULL)             return alias_type(AliasIdxTop);
  if (adr_type == TypePtr::BOTTOM)  return alias_type(AliasIdxBot);

  // Do it the slow way.
  const TypePtr* flat = flatten_alias_type(adr_type);

#ifdef ASSERT
  assert(flat == flatten_alias_type(flat), "idempotent");
  assert(flat != TypePtr::BOTTOM,     "cannot alias-analyze an untyped ptr");
  if (flat->isa_oopptr() && !flat->isa_klassptr()) {
    const TypeOopPtr* foop = flat->is_oopptr();
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    // Scalarizable allocations have exact klass always.
    bool exact = !foop->klass_is_exact() || foop->is_known_instance();
    const TypePtr* xoop = foop->cast_to_exactness(exact)->is_ptr();
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    assert(foop == flatten_alias_type(xoop), "exactness must not affect alias type");
  }
  assert(flat == flatten_alias_type(flat), "exact bit doesn't matter");
#endif

  int idx = AliasIdxTop;
  for (int i = 0; i < num_alias_types(); i++) {
    if (alias_type(i)->adr_type() == flat) {
      idx = i;
      break;
    }
  }

  if (idx == AliasIdxTop) {
    if (no_create)  return NULL;
    // Grow the array if necessary.
    if (_num_alias_types == _max_alias_types)  grow_alias_types();
    // Add a new alias type.
    idx = _num_alias_types++;
    _alias_types[idx]->Init(idx, flat);
    if (flat == TypeInstPtr::KLASS)  alias_type(idx)->set_rewritable(false);
    if (flat == TypeAryPtr::RANGE)   alias_type(idx)->set_rewritable(false);
    if (flat->isa_instptr()) {
      if (flat->offset() == java_lang_Class::klass_offset_in_bytes()
          && flat->is_instptr()->klass() == env()->Class_klass())
        alias_type(idx)->set_rewritable(false);
    }
    if (flat->isa_klassptr()) {
1606
      if (flat->offset() == in_bytes(Klass::super_check_offset_offset()))
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        alias_type(idx)->set_rewritable(false);
1608
      if (flat->offset() == in_bytes(Klass::modifier_flags_offset()))
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        alias_type(idx)->set_rewritable(false);
1610
      if (flat->offset() == in_bytes(Klass::access_flags_offset()))
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        alias_type(idx)->set_rewritable(false);
1612
      if (flat->offset() == in_bytes(Klass::java_mirror_offset()))
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        alias_type(idx)->set_rewritable(false);
    }
    // %%% (We would like to finalize JavaThread::threadObj_offset(),
    // but the base pointer type is not distinctive enough to identify
    // references into JavaThread.)

1619
    // Check for final fields.
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    const TypeInstPtr* tinst = flat->isa_instptr();
1621
    if (tinst && tinst->offset() >= instanceOopDesc::base_offset_in_bytes()) {
1622 1623 1624 1625 1626 1627 1628 1629 1630 1631 1632 1633 1634 1635 1636 1637
      ciField* field;
      if (tinst->const_oop() != NULL &&
          tinst->klass() == ciEnv::current()->Class_klass() &&
          tinst->offset() >= (tinst->klass()->as_instance_klass()->size_helper() * wordSize)) {
        // static field
        ciInstanceKlass* k = tinst->const_oop()->as_instance()->java_lang_Class_klass()->as_instance_klass();
        field = k->get_field_by_offset(tinst->offset(), true);
      } else {
        ciInstanceKlass *k = tinst->klass()->as_instance_klass();
        field = k->get_field_by_offset(tinst->offset(), false);
      }
      assert(field == NULL ||
             original_field == NULL ||
             (field->holder() == original_field->holder() &&
              field->offset() == original_field->offset() &&
              field->is_static() == original_field->is_static()), "wrong field?");
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      // Set field() and is_rewritable() attributes.
      if (field != NULL)  alias_type(idx)->set_field(field);
    }
  }

  // Fill the cache for next time.
  ace->_adr_type = adr_type;
  ace->_index    = idx;
  assert(alias_type(adr_type) == alias_type(idx),  "type must be installed");

  // Might as well try to fill the cache for the flattened version, too.
  AliasCacheEntry* face = probe_alias_cache(flat);
  if (face->_adr_type == NULL) {
    face->_adr_type = flat;
    face->_index    = idx;
    assert(alias_type(flat) == alias_type(idx), "flat type must work too");
  }

  return alias_type(idx);
}


Compile::AliasType* Compile::alias_type(ciField* field) {
  const TypeOopPtr* t;
  if (field->is_static())
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    t = TypeInstPtr::make(field->holder()->java_mirror());
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  else
    t = TypeOopPtr::make_from_klass_raw(field->holder());
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  AliasType* atp = alias_type(t->add_offset(field->offset_in_bytes()), field);
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  assert(field->is_final() == !atp->is_rewritable(), "must get the rewritable bits correct");
  return atp;
}


//------------------------------have_alias_type--------------------------------
bool Compile::have_alias_type(const TypePtr* adr_type) {
  AliasCacheEntry* ace = probe_alias_cache(adr_type);
  if (ace->_adr_type == adr_type) {
    return true;
  }

  // Handle special cases.
  if (adr_type == NULL)             return true;
  if (adr_type == TypePtr::BOTTOM)  return true;

1683
  return find_alias_type(adr_type, true, NULL) != NULL;
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}

//-----------------------------must_alias--------------------------------------
// True if all values of the given address type are in the given alias category.
bool Compile::must_alias(const TypePtr* adr_type, int alias_idx) {
  if (alias_idx == AliasIdxBot)         return true;  // the universal category
  if (adr_type == NULL)                 return true;  // NULL serves as TypePtr::TOP
  if (alias_idx == AliasIdxTop)         return false; // the empty category
  if (adr_type->base() == Type::AnyPtr) return false; // TypePtr::BOTTOM or its twins

  // the only remaining possible overlap is identity
  int adr_idx = get_alias_index(adr_type);
  assert(adr_idx != AliasIdxBot && adr_idx != AliasIdxTop, "");
  assert(adr_idx == alias_idx ||
         (alias_type(alias_idx)->adr_type() != TypeOopPtr::BOTTOM
          && adr_type                       != TypeOopPtr::BOTTOM),
         "should not be testing for overlap with an unsafe pointer");
  return adr_idx == alias_idx;
}

//------------------------------can_alias--------------------------------------
// True if any values of the given address type are in the given alias category.
bool Compile::can_alias(const TypePtr* adr_type, int alias_idx) {
  if (alias_idx == AliasIdxTop)         return false; // the empty category
  if (adr_type == NULL)                 return false; // NULL serves as TypePtr::TOP
  if (alias_idx == AliasIdxBot)         return true;  // the universal category
  if (adr_type->base() == Type::AnyPtr) return true;  // TypePtr::BOTTOM or its twins

  // the only remaining possible overlap is identity
  int adr_idx = get_alias_index(adr_type);
  assert(adr_idx != AliasIdxBot && adr_idx != AliasIdxTop, "");
  return adr_idx == alias_idx;
}



//---------------------------pop_warm_call-------------------------------------
WarmCallInfo* Compile::pop_warm_call() {
  WarmCallInfo* wci = _warm_calls;
  if (wci != NULL)  _warm_calls = wci->remove_from(wci);
  return wci;
}

//----------------------------Inline_Warm--------------------------------------
int Compile::Inline_Warm() {
  // If there is room, try to inline some more warm call sites.
  // %%% Do a graph index compaction pass when we think we're out of space?
  if (!InlineWarmCalls)  return 0;

  int calls_made_hot = 0;
  int room_to_grow   = NodeCountInliningCutoff - unique();
  int amount_to_grow = MIN2(room_to_grow, (int)NodeCountInliningStep);
  int amount_grown   = 0;
  WarmCallInfo* call;
  while (amount_to_grow > 0 && (call = pop_warm_call()) != NULL) {
    int est_size = (int)call->size();
    if (est_size > (room_to_grow - amount_grown)) {
      // This one won't fit anyway.  Get rid of it.
      call->make_cold();
      continue;
    }
    call->make_hot();
    calls_made_hot++;
    amount_grown   += est_size;
    amount_to_grow -= est_size;
  }

  if (calls_made_hot > 0)  set_major_progress();
  return calls_made_hot;
}


//----------------------------Finish_Warm--------------------------------------
void Compile::Finish_Warm() {
  if (!InlineWarmCalls)  return;
  if (failing())  return;
  if (warm_calls() == NULL)  return;

  // Clean up loose ends, if we are out of space for inlining.
  WarmCallInfo* call;
  while ((call = pop_warm_call()) != NULL) {
    call->make_cold();
  }
}

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//---------------------cleanup_loop_predicates-----------------------
// Remove the opaque nodes that protect the predicates so that all unused
// checks and uncommon_traps will be eliminated from the ideal graph
void Compile::cleanup_loop_predicates(PhaseIterGVN &igvn) {
  if (predicate_count()==0) return;
  for (int i = predicate_count(); i > 0; i--) {
    Node * n = predicate_opaque1_node(i-1);
    assert(n->Opcode() == Op_Opaque1, "must be");
    igvn.replace_node(n, n->in(1));
  }
  assert(predicate_count()==0, "should be clean!");
}
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// StringOpts and late inlining of string methods
void Compile::inline_string_calls(bool parse_time) {
  {
    // remove useless nodes to make the usage analysis simpler
    ResourceMark rm;
    PhaseRemoveUseless pru(initial_gvn(), for_igvn());
  }

  {
    ResourceMark rm;
    print_method("Before StringOpts", 3);
    PhaseStringOpts pso(initial_gvn(), for_igvn());
    print_method("After StringOpts", 3);
  }

  // now inline anything that we skipped the first time around
  if (!parse_time) {
    _late_inlines_pos = _late_inlines.length();
  }

  while (_string_late_inlines.length() > 0) {
    CallGenerator* cg = _string_late_inlines.pop();
    cg->do_late_inline();
    if (failing())  return;
  }
  _string_late_inlines.trunc_to(0);
}

void Compile::inline_incrementally_one(PhaseIterGVN& igvn) {
  assert(IncrementalInline, "incremental inlining should be on");
  PhaseGVN* gvn = initial_gvn();

  set_inlining_progress(false);
  for_igvn()->clear();
  gvn->replace_with(&igvn);

  int i = 0;

  for (; i <_late_inlines.length() && !inlining_progress(); i++) {
    CallGenerator* cg = _late_inlines.at(i);
    _late_inlines_pos = i+1;
    cg->do_late_inline();
    if (failing())  return;
  }
  int j = 0;
  for (; i < _late_inlines.length(); i++, j++) {
    _late_inlines.at_put(j, _late_inlines.at(i));
  }
  _late_inlines.trunc_to(j);

  {
    ResourceMark rm;
    PhaseRemoveUseless pru(C->initial_gvn(), C->for_igvn());
  }

  igvn = PhaseIterGVN(gvn);
}

// Perform incremental inlining until bound on number of live nodes is reached
void Compile::inline_incrementally(PhaseIterGVN& igvn) {
  PhaseGVN* gvn = initial_gvn();

  set_inlining_incrementally(true);
  set_inlining_progress(true);
  uint low_live_nodes = 0;

  while(inlining_progress() && _late_inlines.length() > 0) {

    if (live_nodes() > (uint)LiveNodeCountInliningCutoff) {
      if (low_live_nodes < (uint)LiveNodeCountInliningCutoff * 8 / 10) {
        // PhaseIdealLoop is expensive so we only try it once we are
        // out of loop and we only try it again if the previous helped
        // got the number of nodes down significantly
        PhaseIdealLoop ideal_loop( igvn, false, true );
        if (failing())  return;
        low_live_nodes = live_nodes();
        _major_progress = true;
      }

      if (live_nodes() > (uint)LiveNodeCountInliningCutoff) {
        break;
      }
    }

    inline_incrementally_one(igvn);

    if (failing())  return;

    igvn.optimize();

    if (failing())  return;
  }

  assert( igvn._worklist.size() == 0, "should be done with igvn" );

  if (_string_late_inlines.length() > 0) {
    assert(has_stringbuilder(), "inconsistent");
    for_igvn()->clear();
    initial_gvn()->replace_with(&igvn);

    inline_string_calls(false);

    if (failing())  return;

    {
      ResourceMark rm;
      PhaseRemoveUseless pru(initial_gvn(), for_igvn());
    }

    igvn = PhaseIterGVN(gvn);

    igvn.optimize();
  }

  set_inlining_incrementally(false);
}


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//------------------------------Optimize---------------------------------------
// Given a graph, optimize it.
void Compile::Optimize() {
  TracePhase t1("optimizer", &_t_optimizer, true);

#ifndef PRODUCT
  if (env()->break_at_compile()) {
    BREAKPOINT;
  }

#endif

  ResourceMark rm;
  int          loop_opts_cnt;

  NOT_PRODUCT( verify_graph_edges(); )

1917
  print_method("After Parsing");
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 {
  // Iterative Global Value Numbering, including ideal transforms
  // Initialize IterGVN with types and values from parse-time GVN
  PhaseIterGVN igvn(initial_gvn());
  {
    NOT_PRODUCT( TracePhase t2("iterGVN", &_t_iterGVN, TimeCompiler); )
    igvn.optimize();
  }

  print_method("Iter GVN 1", 2);

  if (failing())  return;

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  inline_incrementally(igvn);

  print_method("Incremental Inline", 2);

  if (failing())  return;

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  // No more new expensive nodes will be added to the list from here
  // so keep only the actual candidates for optimizations.
  cleanup_expensive_nodes(igvn);

1942 1943
  // Perform escape analysis
  if (_do_escape_analysis && ConnectionGraph::has_candidates(this)) {
1944 1945 1946 1947 1948 1949 1950
    if (has_loops()) {
      // Cleanup graph (remove dead nodes).
      TracePhase t2("idealLoop", &_t_idealLoop, true);
      PhaseIdealLoop ideal_loop( igvn, false, true );
      if (major_progress()) print_method("PhaseIdealLoop before EA", 2);
      if (failing())  return;
    }
1951 1952 1953 1954
    ConnectionGraph::do_analysis(this, &igvn);

    if (failing())  return;

1955
    // Optimize out fields loads from scalar replaceable allocations.
1956
    igvn.optimize();
1957
    print_method("Iter GVN after EA", 2);
1958 1959 1960

    if (failing())  return;

1961
    if (congraph() != NULL && macro_count() > 0) {
1962
      NOT_PRODUCT( TracePhase t2("macroEliminate", &_t_macroEliminate, TimeCompiler); )
1963 1964 1965 1966 1967 1968 1969 1970 1971
      PhaseMacroExpand mexp(igvn);
      mexp.eliminate_macro_nodes();
      igvn.set_delay_transform(false);

      igvn.optimize();
      print_method("Iter GVN after eliminating allocations and locks", 2);

      if (failing())  return;
    }
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  }

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  // Loop transforms on the ideal graph.  Range Check Elimination,
  // peeling, unrolling, etc.

  // Set loop opts counter
  loop_opts_cnt = num_loop_opts();
  if((loop_opts_cnt > 0) && (has_loops() || has_split_ifs())) {
    {
      TracePhase t2("idealLoop", &_t_idealLoop, true);
1982
      PhaseIdealLoop ideal_loop( igvn, true );
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      loop_opts_cnt--;
      if (major_progress()) print_method("PhaseIdealLoop 1", 2);
      if (failing())  return;
    }
    // Loop opts pass if partial peeling occurred in previous pass
    if(PartialPeelLoop && major_progress() && (loop_opts_cnt > 0)) {
      TracePhase t3("idealLoop", &_t_idealLoop, true);
1990
      PhaseIdealLoop ideal_loop( igvn, false );
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      loop_opts_cnt--;
      if (major_progress()) print_method("PhaseIdealLoop 2", 2);
      if (failing())  return;
    }
    // Loop opts pass for loop-unrolling before CCP
    if(major_progress() && (loop_opts_cnt > 0)) {
      TracePhase t4("idealLoop", &_t_idealLoop, true);
1998
      PhaseIdealLoop ideal_loop( igvn, false );
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      loop_opts_cnt--;
      if (major_progress()) print_method("PhaseIdealLoop 3", 2);
    }
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    if (!failing()) {
      // Verify that last round of loop opts produced a valid graph
      NOT_PRODUCT( TracePhase t2("idealLoopVerify", &_t_idealLoopVerify, TimeCompiler); )
      PhaseIdealLoop::verify(igvn);
    }
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  }
  if (failing())  return;

  // Conditional Constant Propagation;
  PhaseCCP ccp( &igvn );
  assert( true, "Break here to ccp.dump_nodes_and_types(_root,999,1)");
  {
    TracePhase t2("ccp", &_t_ccp, true);
    ccp.do_transform();
  }
  print_method("PhaseCPP 1", 2);

  assert( true, "Break here to ccp.dump_old2new_map()");

  // Iterative Global Value Numbering, including ideal transforms
  {
    NOT_PRODUCT( TracePhase t2("iterGVN2", &_t_iterGVN2, TimeCompiler); )
    igvn = ccp;
    igvn.optimize();
  }

  print_method("Iter GVN 2", 2);

  if (failing())  return;

  // Loop transforms on the ideal graph.  Range Check Elimination,
  // peeling, unrolling, etc.
  if(loop_opts_cnt > 0) {
    debug_only( int cnt = 0; );
    while(major_progress() && (loop_opts_cnt > 0)) {
      TracePhase t2("idealLoop", &_t_idealLoop, true);
      assert( cnt++ < 40, "infinite cycle in loop optimization" );
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      PhaseIdealLoop ideal_loop( igvn, true);
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      loop_opts_cnt--;
      if (major_progress()) print_method("PhaseIdealLoop iterations", 2);
      if (failing())  return;
    }
  }
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  {
    // Verify that all previous optimizations produced a valid graph
    // at least to this point, even if no loop optimizations were done.
    NOT_PRODUCT( TracePhase t2("idealLoopVerify", &_t_idealLoopVerify, TimeCompiler); )
    PhaseIdealLoop::verify(igvn);
  }

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  {
    NOT_PRODUCT( TracePhase t2("macroExpand", &_t_macroExpand, TimeCompiler); )
    PhaseMacroExpand  mex(igvn);
    if (mex.expand_macro_nodes()) {
      assert(failing(), "must bail out w/ explicit message");
      return;
    }
  }

 } // (End scope of igvn; run destructor if necessary for asserts.)

2064
  dump_inlining();
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  // A method with only infinite loops has no edges entering loops from root
  {
    NOT_PRODUCT( TracePhase t2("graphReshape", &_t_graphReshaping, TimeCompiler); )
    if (final_graph_reshaping()) {
      assert(failing(), "must bail out w/ explicit message");
      return;
    }
  }

  print_method("Optimize finished", 2);
}


//------------------------------Code_Gen---------------------------------------
// Given a graph, generate code for it
void Compile::Code_Gen() {
  if (failing())  return;

  // Perform instruction selection.  You might think we could reclaim Matcher
  // memory PDQ, but actually the Matcher is used in generating spill code.
  // Internals of the Matcher (including some VectorSets) must remain live
  // for awhile - thus I cannot reclaim Matcher memory lest a VectorSet usage
  // set a bit in reclaimed memory.

  // In debug mode can dump m._nodes.dump() for mapping of ideal to machine
  // nodes.  Mapping is only valid at the root of each matched subtree.
  NOT_PRODUCT( verify_graph_edges(); )

  Node_List proj_list;
  Matcher m(proj_list);
  _matcher = &m;
  {
    TracePhase t2("matcher", &_t_matcher, true);
    m.match();
  }
  // In debug mode can dump m._nodes.dump() for mapping of ideal to machine
  // nodes.  Mapping is only valid at the root of each matched subtree.
  NOT_PRODUCT( verify_graph_edges(); )

  // If you have too many nodes, or if matching has failed, bail out
  check_node_count(0, "out of nodes matching instructions");
  if (failing())  return;

  // Build a proper-looking CFG
  PhaseCFG cfg(node_arena(), root(), m);
  _cfg = &cfg;
  {
    NOT_PRODUCT( TracePhase t2("scheduler", &_t_scheduler, TimeCompiler); )
    cfg.Dominators();
    if (failing())  return;

    NOT_PRODUCT( verify_graph_edges(); )

    cfg.Estimate_Block_Frequency();
    cfg.GlobalCodeMotion(m,unique(),proj_list);
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    if (failing())  return;
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    print_method("Global code motion", 2);

    NOT_PRODUCT( verify_graph_edges(); )

    debug_only( cfg.verify(); )
  }
  NOT_PRODUCT( verify_graph_edges(); )

  PhaseChaitin regalloc(unique(),cfg,m);
  _regalloc = &regalloc;
  {
    TracePhase t2("regalloc", &_t_registerAllocation, true);
    // Perform any platform dependent preallocation actions.  This is used,
    // for example, to avoid taking an implicit null pointer exception
    // using the frame pointer on win95.
    _regalloc->pd_preallocate_hook();

    // Perform register allocation.  After Chaitin, use-def chains are
    // no longer accurate (at spill code) and so must be ignored.
    // Node->LRG->reg mappings are still accurate.
    _regalloc->Register_Allocate();

    // Bail out if the allocator builds too many nodes
    if (failing())  return;
  }

  // Prior to register allocation we kept empty basic blocks in case the
  // the allocator needed a place to spill.  After register allocation we
  // are not adding any new instructions.  If any basic block is empty, we
  // can now safely remove it.
  {
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    NOT_PRODUCT( TracePhase t2("blockOrdering", &_t_blockOrdering, TimeCompiler); )
    cfg.remove_empty();
    if (do_freq_based_layout()) {
      PhaseBlockLayout layout(cfg);
    } else {
      cfg.set_loop_alignment();
    }
    cfg.fixup_flow();
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  }

  // Perform any platform dependent postallocation verifications.
  debug_only( _regalloc->pd_postallocate_verify_hook(); )

  // Apply peephole optimizations
  if( OptoPeephole ) {
    NOT_PRODUCT( TracePhase t2("peephole", &_t_peephole, TimeCompiler); )
    PhasePeephole peep( _regalloc, cfg);
    peep.do_transform();
  }

  // Convert Nodes to instruction bits in a buffer
  {
    // %%%% workspace merge brought two timers together for one job
    TracePhase t2a("output", &_t_output, true);
    NOT_PRODUCT( TraceTime t2b(NULL, &_t_codeGeneration, TimeCompiler, false); )
    Output();
  }

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  print_method("Final Code");
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  // He's dead, Jim.
  _cfg     = (PhaseCFG*)0xdeadbeef;
  _regalloc = (PhaseChaitin*)0xdeadbeef;
}


//------------------------------dump_asm---------------------------------------
// Dump formatted assembly
#ifndef PRODUCT
void Compile::dump_asm(int *pcs, uint pc_limit) {
  bool cut_short = false;
  tty->print_cr("#");
  tty->print("#  ");  _tf->dump();  tty->cr();
  tty->print_cr("#");

  // For all blocks
  int pc = 0x0;                 // Program counter
  char starts_bundle = ' ';
  _regalloc->dump_frame();

  Node *n = NULL;
  for( uint i=0; i<_cfg->_num_blocks; i++ ) {
    if (VMThread::should_terminate()) { cut_short = true; break; }
    Block *b = _cfg->_blocks[i];
    if (b->is_connector() && !Verbose) continue;
    n = b->_nodes[0];
    if (pcs && n->_idx < pc_limit)
      tty->print("%3.3x   ", pcs[n->_idx]);
    else
      tty->print("      ");
    b->dump_head( &_cfg->_bbs );
    if (b->is_connector()) {
      tty->print_cr("        # Empty connector block");
    } else if (b->num_preds() == 2 && b->pred(1)->is_CatchProj() && b->pred(1)->as_CatchProj()->_con == CatchProjNode::fall_through_index) {
      tty->print_cr("        # Block is sole successor of call");
    }

    // For all instructions
    Node *delay = NULL;
    for( uint j = 0; j<b->_nodes.size(); j++ ) {
      if (VMThread::should_terminate()) { cut_short = true; break; }
      n = b->_nodes[j];
      if (valid_bundle_info(n)) {
        Bundle *bundle = node_bundling(n);
        if (bundle->used_in_unconditional_delay()) {
          delay = n;
          continue;
        }
        if (bundle->starts_bundle())
          starts_bundle = '+';
      }

2235 2236
      if (WizardMode) n->dump();

D
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2237 2238 2239 2240
      if( !n->is_Region() &&    // Dont print in the Assembly
          !n->is_Phi() &&       // a few noisely useless nodes
          !n->is_Proj() &&
          !n->is_MachTemp() &&
2241
          !n->is_SafePointScalarObject() &&
D
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2242 2243 2244 2245 2246 2247 2248 2249 2250 2251 2252 2253 2254 2255 2256 2257 2258 2259 2260 2261
          !n->is_Catch() &&     // Would be nice to print exception table targets
          !n->is_MergeMem() &&  // Not very interesting
          !n->is_top() &&       // Debug info table constants
          !(n->is_Con() && !n->is_Mach())// Debug info table constants
          ) {
        if (pcs && n->_idx < pc_limit)
          tty->print("%3.3x", pcs[n->_idx]);
        else
          tty->print("   ");
        tty->print(" %c ", starts_bundle);
        starts_bundle = ' ';
        tty->print("\t");
        n->format(_regalloc, tty);
        tty->cr();
      }

      // If we have an instruction with a delay slot, and have seen a delay,
      // then back up and print it
      if (valid_bundle_info(n) && node_bundling(n)->use_unconditional_delay()) {
        assert(delay != NULL, "no unconditional delay instruction");
2262 2263
        if (WizardMode) delay->dump();

D
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2264 2265 2266 2267 2268 2269 2270 2271 2272 2273 2274 2275 2276 2277 2278 2279 2280 2281 2282 2283 2284 2285 2286 2287 2288 2289 2290 2291 2292 2293 2294 2295 2296 2297 2298 2299 2300 2301 2302 2303 2304 2305 2306
        if (node_bundling(delay)->starts_bundle())
          starts_bundle = '+';
        if (pcs && n->_idx < pc_limit)
          tty->print("%3.3x", pcs[n->_idx]);
        else
          tty->print("   ");
        tty->print(" %c ", starts_bundle);
        starts_bundle = ' ';
        tty->print("\t");
        delay->format(_regalloc, tty);
        tty->print_cr("");
        delay = NULL;
      }

      // Dump the exception table as well
      if( n->is_Catch() && (Verbose || WizardMode) ) {
        // Print the exception table for this offset
        _handler_table.print_subtable_for(pc);
      }
    }

    if (pcs && n->_idx < pc_limit)
      tty->print_cr("%3.3x", pcs[n->_idx]);
    else
      tty->print_cr("");

    assert(cut_short || delay == NULL, "no unconditional delay branch");

  } // End of per-block dump
  tty->print_cr("");

  if (cut_short)  tty->print_cr("*** disassembly is cut short ***");
}
#endif

//------------------------------Final_Reshape_Counts---------------------------
// This class defines counters to help identify when a method
// may/must be executed using hardware with only 24-bit precision.
struct Final_Reshape_Counts : public StackObj {
  int  _call_count;             // count non-inlined 'common' calls
  int  _float_count;            // count float ops requiring 24-bit precision
  int  _double_count;           // count double ops requiring more precision
  int  _java_call_count;        // count non-inlined 'java' calls
2307
  int  _inner_loop_count;       // count loops which need alignment
D
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2308 2309 2310 2311
  VectorSet _visited;           // Visitation flags
  Node_List _tests;             // Set of IfNodes & PCTableNodes

  Final_Reshape_Counts() :
2312 2313
    _call_count(0), _float_count(0), _double_count(0),
    _java_call_count(0), _inner_loop_count(0),
D
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2314 2315 2316 2317 2318 2319
    _visited( Thread::current()->resource_area() ) { }

  void inc_call_count  () { _call_count  ++; }
  void inc_float_count () { _float_count ++; }
  void inc_double_count() { _double_count++; }
  void inc_java_call_count() { _java_call_count++; }
2320
  void inc_inner_loop_count() { _inner_loop_count++; }
D
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2321 2322 2323 2324 2325

  int  get_call_count  () const { return _call_count  ; }
  int  get_float_count () const { return _float_count ; }
  int  get_double_count() const { return _double_count; }
  int  get_java_call_count() const { return _java_call_count; }
2326
  int  get_inner_loop_count() const { return _inner_loop_count; }
D
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2327 2328
};

2329
#ifdef ASSERT
D
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2330 2331 2332
static bool oop_offset_is_sane(const TypeInstPtr* tp) {
  ciInstanceKlass *k = tp->klass()->as_instance_klass();
  // Make sure the offset goes inside the instance layout.
2333
  return k->contains_field_offset(tp->offset());
D
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2334 2335
  // Note that OffsetBot and OffsetTop are very negative.
}
2336
#endif
D
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2337

2338 2339
// Eliminate trivially redundant StoreCMs and accumulate their
// precedence edges.
2340
void Compile::eliminate_redundant_card_marks(Node* n) {
2341 2342 2343 2344 2345 2346 2347 2348 2349 2350 2351 2352 2353 2354 2355 2356 2357 2358 2359 2360 2361 2362 2363 2364 2365 2366 2367 2368 2369 2370 2371 2372 2373 2374
  assert(n->Opcode() == Op_StoreCM, "expected StoreCM");
  if (n->in(MemNode::Address)->outcnt() > 1) {
    // There are multiple users of the same address so it might be
    // possible to eliminate some of the StoreCMs
    Node* mem = n->in(MemNode::Memory);
    Node* adr = n->in(MemNode::Address);
    Node* val = n->in(MemNode::ValueIn);
    Node* prev = n;
    bool done = false;
    // Walk the chain of StoreCMs eliminating ones that match.  As
    // long as it's a chain of single users then the optimization is
    // safe.  Eliminating partially redundant StoreCMs would require
    // cloning copies down the other paths.
    while (mem->Opcode() == Op_StoreCM && mem->outcnt() == 1 && !done) {
      if (adr == mem->in(MemNode::Address) &&
          val == mem->in(MemNode::ValueIn)) {
        // redundant StoreCM
        if (mem->req() > MemNode::OopStore) {
          // Hasn't been processed by this code yet.
          n->add_prec(mem->in(MemNode::OopStore));
        } else {
          // Already converted to precedence edge
          for (uint i = mem->req(); i < mem->len(); i++) {
            // Accumulate any precedence edges
            if (mem->in(i) != NULL) {
              n->add_prec(mem->in(i));
            }
          }
          // Everything above this point has been processed.
          done = true;
        }
        // Eliminate the previous StoreCM
        prev->set_req(MemNode::Memory, mem->in(MemNode::Memory));
        assert(mem->outcnt() == 0, "should be dead");
2375
        mem->disconnect_inputs(NULL, this);
2376 2377 2378 2379 2380 2381 2382 2383
      } else {
        prev = mem;
      }
      mem = prev->in(MemNode::Memory);
    }
  }
}

D
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2384 2385
//------------------------------final_graph_reshaping_impl----------------------
// Implement items 1-5 from final_graph_reshaping below.
2386
void Compile::final_graph_reshaping_impl( Node *n, Final_Reshape_Counts &frc) {
D
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2387

2388
  if ( n->outcnt() == 0 ) return; // dead node
D
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2389 2390 2391 2392 2393 2394 2395 2396 2397 2398 2399 2400 2401 2402 2403 2404 2405 2406 2407 2408 2409 2410 2411 2412 2413
  uint nop = n->Opcode();

  // Check for 2-input instruction with "last use" on right input.
  // Swap to left input.  Implements item (2).
  if( n->req() == 3 &&          // two-input instruction
      n->in(1)->outcnt() > 1 && // left use is NOT a last use
      (!n->in(1)->is_Phi() || n->in(1)->in(2) != n) && // it is not data loop
      n->in(2)->outcnt() == 1 &&// right use IS a last use
      !n->in(2)->is_Con() ) {   // right use is not a constant
    // Check for commutative opcode
    switch( nop ) {
    case Op_AddI:  case Op_AddF:  case Op_AddD:  case Op_AddL:
    case Op_MaxI:  case Op_MinI:
    case Op_MulI:  case Op_MulF:  case Op_MulD:  case Op_MulL:
    case Op_AndL:  case Op_XorL:  case Op_OrL:
    case Op_AndI:  case Op_XorI:  case Op_OrI: {
      // Move "last use" input to left by swapping inputs
      n->swap_edges(1, 2);
      break;
    }
    default:
      break;
    }
  }

2414 2415
#ifdef ASSERT
  if( n->is_Mem() ) {
2416
    int alias_idx = get_alias_index(n->as_Mem()->adr_type());
2417 2418 2419 2420 2421 2422 2423
    assert( n->in(0) != NULL || alias_idx != Compile::AliasIdxRaw ||
            // oop will be recorded in oop map if load crosses safepoint
            n->is_Load() && (n->as_Load()->bottom_type()->isa_oopptr() ||
                             LoadNode::is_immutable_value(n->in(MemNode::Address))),
            "raw memory operations should have control edge");
  }
#endif
D
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2424 2425 2426 2427 2428 2429 2430 2431 2432 2433 2434 2435 2436 2437
  // Count FPU ops and common calls, implements item (3)
  switch( nop ) {
  // Count all float operations that may use FPU
  case Op_AddF:
  case Op_SubF:
  case Op_MulF:
  case Op_DivF:
  case Op_NegF:
  case Op_ModF:
  case Op_ConvI2F:
  case Op_ConF:
  case Op_CmpF:
  case Op_CmpF3:
  // case Op_ConvL2F: // longs are split into 32-bit halves
2438
    frc.inc_float_count();
D
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2439 2440 2441 2442
    break;

  case Op_ConvF2D:
  case Op_ConvD2F:
2443 2444
    frc.inc_float_count();
    frc.inc_double_count();
D
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2445 2446 2447 2448 2449 2450 2451 2452 2453 2454 2455 2456 2457 2458 2459 2460
    break;

  // Count all double operations that may use FPU
  case Op_AddD:
  case Op_SubD:
  case Op_MulD:
  case Op_DivD:
  case Op_NegD:
  case Op_ModD:
  case Op_ConvI2D:
  case Op_ConvD2I:
  // case Op_ConvL2D: // handled by leaf call
  // case Op_ConvD2L: // handled by leaf call
  case Op_ConD:
  case Op_CmpD:
  case Op_CmpD3:
2461
    frc.inc_double_count();
D
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2462 2463 2464
    break;
  case Op_Opaque1:              // Remove Opaque Nodes before matching
  case Op_Opaque2:              // Remove Opaque Nodes before matching
2465
    n->subsume_by(n->in(1), this);
D
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2466 2467 2468 2469
    break;
  case Op_CallStaticJava:
  case Op_CallJava:
  case Op_CallDynamicJava:
2470
    frc.inc_java_call_count(); // Count java call site;
D
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2471 2472 2473 2474 2475 2476 2477 2478 2479 2480
  case Op_CallRuntime:
  case Op_CallLeaf:
  case Op_CallLeafNoFP: {
    assert( n->is_Call(), "" );
    CallNode *call = n->as_Call();
    // Count call sites where the FP mode bit would have to be flipped.
    // Do not count uncommon runtime calls:
    // uncommon_trap, _complete_monitor_locking, _complete_monitor_unlocking,
    // _new_Java, _new_typeArray, _new_objArray, _rethrow_Java, ...
    if( !call->is_CallStaticJava() || !call->as_CallStaticJava()->_name ) {
2481
      frc.inc_call_count();   // Count the call site
D
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2482 2483 2484 2485 2486 2487 2488 2489
    } else {                  // See if uncommon argument is shared
      Node *n = call->in(TypeFunc::Parms);
      int nop = n->Opcode();
      // Clone shared simple arguments to uncommon calls, item (1).
      if( n->outcnt() > 1 &&
          !n->is_Proj() &&
          nop != Op_CreateEx &&
          nop != Op_CheckCastPP &&
2490
          nop != Op_DecodeN &&
2491
          nop != Op_DecodeNKlass &&
D
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2492 2493 2494 2495 2496 2497 2498 2499 2500 2501 2502
          !n->is_Mem() ) {
        Node *x = n->clone();
        call->set_req( TypeFunc::Parms, x );
      }
    }
    break;
  }

  case Op_StoreD:
  case Op_LoadD:
  case Op_LoadD_unaligned:
2503
    frc.inc_double_count();
D
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2504 2505 2506
    goto handle_mem;
  case Op_StoreF:
  case Op_LoadF:
2507
    frc.inc_float_count();
D
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2508 2509
    goto handle_mem;

2510 2511 2512 2513 2514 2515 2516 2517 2518 2519 2520
  case Op_StoreCM:
    {
      // Convert OopStore dependence into precedence edge
      Node* prec = n->in(MemNode::OopStore);
      n->del_req(MemNode::OopStore);
      n->add_prec(prec);
      eliminate_redundant_card_marks(n);
    }

    // fall through

D
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2521 2522 2523 2524 2525
  case Op_StoreB:
  case Op_StoreC:
  case Op_StorePConditional:
  case Op_StoreI:
  case Op_StoreL:
2526
  case Op_StoreIConditional:
D
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2527 2528 2529 2530
  case Op_StoreLConditional:
  case Op_CompareAndSwapI:
  case Op_CompareAndSwapL:
  case Op_CompareAndSwapP:
2531
  case Op_CompareAndSwapN:
2532 2533 2534 2535 2536 2537
  case Op_GetAndAddI:
  case Op_GetAndAddL:
  case Op_GetAndSetI:
  case Op_GetAndSetL:
  case Op_GetAndSetP:
  case Op_GetAndSetN:
D
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2538
  case Op_StoreP:
2539
  case Op_StoreN:
2540
  case Op_StoreNKlass:
D
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2541
  case Op_LoadB:
2542
  case Op_LoadUB:
2543
  case Op_LoadUS:
D
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2544 2545
  case Op_LoadI:
  case Op_LoadKlass:
2546
  case Op_LoadNKlass:
D
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2547 2548 2549 2550
  case Op_LoadL:
  case Op_LoadL_unaligned:
  case Op_LoadPLocked:
  case Op_LoadP:
2551
  case Op_LoadN:
D
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2552 2553 2554 2555 2556 2557 2558 2559 2560 2561 2562 2563 2564 2565 2566 2567
  case Op_LoadRange:
  case Op_LoadS: {
  handle_mem:
#ifdef ASSERT
    if( VerifyOptoOopOffsets ) {
      assert( n->is_Mem(), "" );
      MemNode *mem  = (MemNode*)n;
      // Check to see if address types have grounded out somehow.
      const TypeInstPtr *tp = mem->in(MemNode::Address)->bottom_type()->isa_instptr();
      assert( !tp || oop_offset_is_sane(tp), "" );
    }
#endif
    break;
  }

  case Op_AddP: {               // Assert sane base pointers
2568
    Node *addp = n->in(AddPNode::Address);
D
duke 已提交
2569 2570 2571 2572
    assert( !addp->is_AddP() ||
            addp->in(AddPNode::Base)->is_top() || // Top OK for allocation
            addp->in(AddPNode::Base) == n->in(AddPNode::Base),
            "Base pointers must match" );
2573
#ifdef _LP64
2574
    if ((UseCompressedOops || UseCompressedKlassPointers) &&
2575 2576 2577 2578 2579 2580 2581 2582
        addp->Opcode() == Op_ConP &&
        addp == n->in(AddPNode::Base) &&
        n->in(AddPNode::Offset)->is_Con()) {
      // Use addressing with narrow klass to load with offset on x86.
      // On sparc loading 32-bits constant and decoding it have less
      // instructions (4) then load 64-bits constant (7).
      // Do this transformation here since IGVN will convert ConN back to ConP.
      const Type* t = addp->bottom_type();
2583
      if (t->isa_oopptr() || t->isa_klassptr()) {
2584 2585
        Node* nn = NULL;

2586 2587
        int op = t->isa_oopptr() ? Op_ConN : Op_ConNKlass;

2588
        // Look for existing ConN node of the same exact type.
2589
        Node* r  = root();
2590 2591 2592
        uint cnt = r->outcnt();
        for (uint i = 0; i < cnt; i++) {
          Node* m = r->raw_out(i);
2593
          if (m!= NULL && m->Opcode() == op &&
2594
              m->bottom_type()->make_ptr() == t) {
2595 2596 2597 2598 2599 2600 2601
            nn = m;
            break;
          }
        }
        if (nn != NULL) {
          // Decode a narrow oop to match address
          // [R12 + narrow_oop_reg<<3 + offset]
2602
          if (t->isa_oopptr()) {
2603
            nn = new (this) DecodeNNode(nn, t);
2604
          } else {
2605
            nn = new (this) DecodeNKlassNode(nn, t);
2606
          }
2607 2608 2609
          n->set_req(AddPNode::Base, nn);
          n->set_req(AddPNode::Address, nn);
          if (addp->outcnt() == 0) {
2610
            addp->disconnect_inputs(NULL, this);
2611 2612 2613 2614 2615
          }
        }
      }
    }
#endif
D
duke 已提交
2616 2617 2618
    break;
  }

2619
#ifdef _LP64
2620
  case Op_CastPP:
2621
    if (n->in(1)->is_DecodeN() && Matcher::gen_narrow_oop_implicit_null_checks()) {
2622 2623 2624 2625 2626
      Node* in1 = n->in(1);
      const Type* t = n->bottom_type();
      Node* new_in1 = in1->clone();
      new_in1->as_DecodeN()->set_type(t);

2627
      if (!Matcher::narrow_oop_use_complex_address()) {
2628 2629 2630 2631 2632 2633 2634 2635 2636 2637 2638 2639 2640 2641 2642
        //
        // x86, ARM and friends can handle 2 adds in addressing mode
        // and Matcher can fold a DecodeN node into address by using
        // a narrow oop directly and do implicit NULL check in address:
        //
        // [R12 + narrow_oop_reg<<3 + offset]
        // NullCheck narrow_oop_reg
        //
        // On other platforms (Sparc) we have to keep new DecodeN node and
        // use it to do implicit NULL check in address:
        //
        // decode_not_null narrow_oop_reg, base_reg
        // [base_reg + offset]
        // NullCheck base_reg
        //
T
twisti 已提交
2643
        // Pin the new DecodeN node to non-null path on these platform (Sparc)
2644 2645 2646 2647 2648 2649
        // to keep the information to which NULL check the new DecodeN node
        // corresponds to use it as value in implicit_null_check().
        //
        new_in1->set_req(0, n->in(0));
      }

2650
      n->subsume_by(new_in1, this);
2651
      if (in1->outcnt() == 0) {
2652
        in1->disconnect_inputs(NULL, this);
2653 2654 2655 2656
      }
    }
    break;

2657
  case Op_CmpP:
2658 2659
    // Do this transformation here to preserve CmpPNode::sub() and
    // other TypePtr related Ideal optimizations (for example, ptr nullness).
2660
    if (n->in(1)->is_DecodeNarrowPtr() || n->in(2)->is_DecodeNarrowPtr()) {
2661 2662
      Node* in1 = n->in(1);
      Node* in2 = n->in(2);
2663
      if (!in1->is_DecodeNarrowPtr()) {
2664 2665 2666
        in2 = in1;
        in1 = n->in(2);
      }
2667
      assert(in1->is_DecodeNarrowPtr(), "sanity");
2668 2669

      Node* new_in2 = NULL;
2670 2671
      if (in2->is_DecodeNarrowPtr()) {
        assert(in2->Opcode() == in1->Opcode(), "must be same node type");
2672 2673 2674
        new_in2 = in2->in(1);
      } else if (in2->Opcode() == Op_ConP) {
        const Type* t = in2->bottom_type();
2675
        if (t == TypePtr::NULL_PTR) {
2676
          assert(in1->is_DecodeN(), "compare klass to null?");
2677 2678 2679 2680
          // Don't convert CmpP null check into CmpN if compressed
          // oops implicit null check is not generated.
          // This will allow to generate normal oop implicit null check.
          if (Matcher::gen_narrow_oop_implicit_null_checks())
2681
            new_in2 = ConNode::make(this, TypeNarrowOop::NULL_PTR);
2682 2683 2684 2685 2686 2687 2688 2689 2690 2691 2692 2693 2694 2695 2696 2697 2698 2699 2700 2701 2702 2703 2704 2705 2706 2707 2708 2709 2710 2711 2712 2713 2714 2715 2716 2717 2718
          //
          // This transformation together with CastPP transformation above
          // will generated code for implicit NULL checks for compressed oops.
          //
          // The original code after Optimize()
          //
          //    LoadN memory, narrow_oop_reg
          //    decode narrow_oop_reg, base_reg
          //    CmpP base_reg, NULL
          //    CastPP base_reg // NotNull
          //    Load [base_reg + offset], val_reg
          //
          // after these transformations will be
          //
          //    LoadN memory, narrow_oop_reg
          //    CmpN narrow_oop_reg, NULL
          //    decode_not_null narrow_oop_reg, base_reg
          //    Load [base_reg + offset], val_reg
          //
          // and the uncommon path (== NULL) will use narrow_oop_reg directly
          // since narrow oops can be used in debug info now (see the code in
          // final_graph_reshaping_walk()).
          //
          // At the end the code will be matched to
          // on x86:
          //
          //    Load_narrow_oop memory, narrow_oop_reg
          //    Load [R12 + narrow_oop_reg<<3 + offset], val_reg
          //    NullCheck narrow_oop_reg
          //
          // and on sparc:
          //
          //    Load_narrow_oop memory, narrow_oop_reg
          //    decode_not_null narrow_oop_reg, base_reg
          //    Load [base_reg + offset], val_reg
          //    NullCheck base_reg
          //
2719
        } else if (t->isa_oopptr()) {
2720
          new_in2 = ConNode::make(this, t->make_narrowoop());
2721
        } else if (t->isa_klassptr()) {
2722
          new_in2 = ConNode::make(this, t->make_narrowklass());
2723 2724
        }
      }
2725
      if (new_in2 != NULL) {
2726 2727
        Node* cmpN = new (this) CmpNNode(in1->in(1), new_in2);
        n->subsume_by(cmpN, this);
2728
        if (in1->outcnt() == 0) {
2729
          in1->disconnect_inputs(NULL, this);
2730 2731
        }
        if (in2->outcnt() == 0) {
2732
          in2->disconnect_inputs(NULL, this);
2733
        }
2734 2735
      }
    }
2736
    break;
2737 2738

  case Op_DecodeN:
2739 2740
  case Op_DecodeNKlass:
    assert(!n->in(1)->is_EncodeNarrowPtr(), "should be optimized out");
2741
    // DecodeN could be pinned when it can't be fold into
2742
    // an address expression, see the code for Op_CastPP above.
2743
    assert(n->in(0) == NULL || (UseCompressedOops && !Matcher::narrow_oop_use_complex_address()), "no control");
2744 2745
    break;

2746 2747
  case Op_EncodeP:
  case Op_EncodePKlass: {
2748
    Node* in1 = n->in(1);
2749
    if (in1->is_DecodeNarrowPtr()) {
2750
      n->subsume_by(in1->in(1), this);
2751 2752 2753
    } else if (in1->Opcode() == Op_ConP) {
      const Type* t = in1->bottom_type();
      if (t == TypePtr::NULL_PTR) {
2754
        assert(t->isa_oopptr(), "null klass?");
2755
        n->subsume_by(ConNode::make(this, TypeNarrowOop::NULL_PTR), this);
2756
      } else if (t->isa_oopptr()) {
2757
        n->subsume_by(ConNode::make(this, t->make_narrowoop()), this);
2758
      } else if (t->isa_klassptr()) {
2759
        n->subsume_by(ConNode::make(this, t->make_narrowklass()), this);
2760 2761 2762
      }
    }
    if (in1->outcnt() == 0) {
2763
      in1->disconnect_inputs(NULL, this);
2764 2765 2766 2767
    }
    break;
  }

2768 2769 2770 2771 2772 2773 2774 2775 2776 2777 2778 2779 2780 2781 2782 2783 2784
  case Op_Proj: {
    if (OptimizeStringConcat) {
      ProjNode* p = n->as_Proj();
      if (p->_is_io_use) {
        // Separate projections were used for the exception path which
        // are normally removed by a late inline.  If it wasn't inlined
        // then they will hang around and should just be replaced with
        // the original one.
        Node* proj = NULL;
        // Replace with just one
        for (SimpleDUIterator i(p->in(0)); i.has_next(); i.next()) {
          Node *use = i.get();
          if (use->is_Proj() && p != use && use->as_Proj()->_con == p->_con) {
            proj = use;
            break;
          }
        }
K
kvn 已提交
2785
        assert(proj != NULL, "must be found");
2786
        p->subsume_by(proj, this);
2787 2788 2789 2790 2791
      }
    }
    break;
  }

2792
  case Op_Phi:
2793
    if (n->as_Phi()->bottom_type()->isa_narrowoop() || n->as_Phi()->bottom_type()->isa_narrowklass()) {
2794 2795 2796 2797 2798 2799 2800 2801 2802 2803 2804 2805
      // The EncodeP optimization may create Phi with the same edges
      // for all paths. It is not handled well by Register Allocator.
      Node* unique_in = n->in(1);
      assert(unique_in != NULL, "");
      uint cnt = n->req();
      for (uint i = 2; i < cnt; i++) {
        Node* m = n->in(i);
        assert(m != NULL, "");
        if (unique_in != m)
          unique_in = NULL;
      }
      if (unique_in != NULL) {
2806
        n->subsume_by(unique_in, this);
2807 2808 2809 2810
      }
    }
    break;

2811 2812
#endif

D
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2813 2814 2815 2816 2817 2818 2819
  case Op_ModI:
    if (UseDivMod) {
      // Check if a%b and a/b both exist
      Node* d = n->find_similar(Op_DivI);
      if (d) {
        // Replace them with a fused divmod if supported
        if (Matcher::has_match_rule(Op_DivModI)) {
2820 2821 2822
          DivModINode* divmod = DivModINode::make(this, n);
          d->subsume_by(divmod->div_proj(), this);
          n->subsume_by(divmod->mod_proj(), this);
D
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2823 2824
        } else {
          // replace a%b with a-((a/b)*b)
2825 2826 2827
          Node* mult = new (this) MulINode(d, d->in(2));
          Node* sub  = new (this) SubINode(d->in(1), mult);
          n->subsume_by(sub, this);
D
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2828 2829 2830 2831 2832 2833 2834 2835 2836 2837 2838 2839
        }
      }
    }
    break;

  case Op_ModL:
    if (UseDivMod) {
      // Check if a%b and a/b both exist
      Node* d = n->find_similar(Op_DivL);
      if (d) {
        // Replace them with a fused divmod if supported
        if (Matcher::has_match_rule(Op_DivModL)) {
2840 2841 2842
          DivModLNode* divmod = DivModLNode::make(this, n);
          d->subsume_by(divmod->div_proj(), this);
          n->subsume_by(divmod->mod_proj(), this);
D
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2843 2844
        } else {
          // replace a%b with a-((a/b)*b)
2845 2846 2847
          Node* mult = new (this) MulLNode(d, d->in(2));
          Node* sub  = new (this) SubLNode(d->in(1), mult);
          n->subsume_by(sub, this);
D
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2848 2849 2850 2851 2852
        }
      }
    }
    break;

2853 2854
  case Op_LoadVector:
  case Op_StoreVector:
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2855 2856 2857 2858 2859 2860 2861 2862 2863 2864 2865
    break;

  case Op_PackB:
  case Op_PackS:
  case Op_PackI:
  case Op_PackF:
  case Op_PackL:
  case Op_PackD:
    if (n->req()-1 > 2) {
      // Replace many operand PackNodes with a binary tree for matching
      PackNode* p = (PackNode*) n;
2866 2867
      Node* btp = p->binary_tree_pack(this, 1, n->req());
      n->subsume_by(btp, this);
D
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2868 2869
    }
    break;
2870 2871 2872 2873 2874 2875
  case Op_Loop:
  case Op_CountedLoop:
    if (n->as_Loop()->is_inner_loop()) {
      frc.inc_inner_loop_count();
    }
    break;
2876 2877 2878 2879 2880 2881 2882 2883 2884 2885 2886 2887 2888 2889 2890
  case Op_LShiftI:
  case Op_RShiftI:
  case Op_URShiftI:
  case Op_LShiftL:
  case Op_RShiftL:
  case Op_URShiftL:
    if (Matcher::need_masked_shift_count) {
      // The cpu's shift instructions don't restrict the count to the
      // lower 5/6 bits. We need to do the masking ourselves.
      Node* in2 = n->in(2);
      juint mask = (n->bottom_type() == TypeInt::INT) ? (BitsPerInt - 1) : (BitsPerLong - 1);
      const TypeInt* t = in2->find_int_type();
      if (t != NULL && t->is_con()) {
        juint shift = t->get_con();
        if (shift > mask) { // Unsigned cmp
2891
          n->set_req(2, ConNode::make(this, TypeInt::make(shift & mask)));
2892 2893 2894
        }
      } else {
        if (t == NULL || t->_lo < 0 || t->_hi > (int)mask) {
2895
          Node* shift = new (this) AndINode(in2, ConNode::make(this, TypeInt::make(mask)));
2896 2897 2898 2899
          n->set_req(2, shift);
        }
      }
      if (in2->outcnt() == 0) { // Remove dead node
2900
        in2->disconnect_inputs(NULL, this);
2901 2902 2903
      }
    }
    break;
2904 2905 2906 2907 2908 2909 2910
  case Op_MemBarStoreStore:
    // Break the link with AllocateNode: it is no longer useful and
    // confuses register allocation.
    if (n->req() > MemBarNode::Precedent) {
      n->set_req(MemBarNode::Precedent, top());
    }
    break;
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2911 2912 2913 2914 2915
  default:
    assert( !n->is_Call(), "" );
    assert( !n->is_Mem(), "" );
    break;
  }
2916 2917 2918

  // Collect CFG split points
  if (n->is_MultiBranch())
2919
    frc._tests.push(n);
D
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2920 2921 2922 2923 2924
}

//------------------------------final_graph_reshaping_walk---------------------
// Replacing Opaque nodes with their input in final_graph_reshaping_impl(),
// requires that the walk visits a node's inputs before visiting the node.
2925
void Compile::final_graph_reshaping_walk( Node_Stack &nstack, Node *root, Final_Reshape_Counts &frc ) {
2926 2927 2928
  ResourceArea *area = Thread::current()->resource_area();
  Unique_Node_List sfpt(area);

2929
  frc._visited.set(root->_idx); // first, mark node as visited
D
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2930 2931 2932 2933 2934 2935 2936 2937
  uint cnt = root->req();
  Node *n = root;
  uint  i = 0;
  while (true) {
    if (i < cnt) {
      // Place all non-visited non-null inputs onto stack
      Node* m = n->in(i);
      ++i;
2938
      if (m != NULL && !frc._visited.test_set(m->_idx)) {
2939 2940
        if (m->is_SafePoint() && m->as_SafePoint()->jvms() != NULL)
          sfpt.push(m);
D
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2941 2942 2943 2944 2945 2946 2947
        cnt = m->req();
        nstack.push(n, i); // put on stack parent and next input's index
        n = m;
        i = 0;
      }
    } else {
      // Now do post-visit work
2948
      final_graph_reshaping_impl( n, frc );
D
duke 已提交
2949 2950 2951 2952 2953 2954 2955 2956
      if (nstack.is_empty())
        break;             // finished
      n = nstack.node();   // Get node from stack
      cnt = n->req();
      i = nstack.index();
      nstack.pop();        // Shift to the next node on stack
    }
  }
2957

2958
  // Skip next transformation if compressed oops are not used.
2959 2960
  if ((UseCompressedOops && !Matcher::gen_narrow_oop_implicit_null_checks()) ||
      (!UseCompressedOops && !UseCompressedKlassPointers))
2961 2962
    return;

2963
  // Go over safepoints nodes to skip DecodeN/DecodeNKlass nodes for debug edges.
2964
  // It could be done for an uncommon traps or any safepoints/calls
2965
  // if the DecodeN/DecodeNKlass node is referenced only in a debug info.
2966 2967 2968 2969 2970 2971 2972 2973 2974 2975
  while (sfpt.size() > 0) {
    n = sfpt.pop();
    JVMState *jvms = n->as_SafePoint()->jvms();
    assert(jvms != NULL, "sanity");
    int start = jvms->debug_start();
    int end   = n->req();
    bool is_uncommon = (n->is_CallStaticJava() &&
                        n->as_CallStaticJava()->uncommon_trap_request() != 0);
    for (int j = start; j < end; j++) {
      Node* in = n->in(j);
2976
      if (in->is_DecodeNarrowPtr()) {
2977 2978 2979 2980 2981 2982 2983 2984 2985 2986 2987 2988 2989 2990 2991
        bool safe_to_skip = true;
        if (!is_uncommon ) {
          // Is it safe to skip?
          for (uint i = 0; i < in->outcnt(); i++) {
            Node* u = in->raw_out(i);
            if (!u->is_SafePoint() ||
                 u->is_Call() && u->as_Call()->has_non_debug_use(n)) {
              safe_to_skip = false;
            }
          }
        }
        if (safe_to_skip) {
          n->set_req(j, in->in(1));
        }
        if (in->outcnt() == 0) {
2992
          in->disconnect_inputs(NULL, this);
2993 2994 2995 2996
        }
      }
    }
  }
D
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2997 2998 2999 3000 3001 3002 3003 3004 3005 3006 3007 3008 3009 3010 3011 3012 3013 3014 3015 3016 3017 3018 3019 3020 3021 3022 3023 3024 3025 3026 3027 3028 3029 3030 3031 3032 3033
}

//------------------------------final_graph_reshaping--------------------------
// Final Graph Reshaping.
//
// (1) Clone simple inputs to uncommon calls, so they can be scheduled late
//     and not commoned up and forced early.  Must come after regular
//     optimizations to avoid GVN undoing the cloning.  Clone constant
//     inputs to Loop Phis; these will be split by the allocator anyways.
//     Remove Opaque nodes.
// (2) Move last-uses by commutative operations to the left input to encourage
//     Intel update-in-place two-address operations and better register usage
//     on RISCs.  Must come after regular optimizations to avoid GVN Ideal
//     calls canonicalizing them back.
// (3) Count the number of double-precision FP ops, single-precision FP ops
//     and call sites.  On Intel, we can get correct rounding either by
//     forcing singles to memory (requires extra stores and loads after each
//     FP bytecode) or we can set a rounding mode bit (requires setting and
//     clearing the mode bit around call sites).  The mode bit is only used
//     if the relative frequency of single FP ops to calls is low enough.
//     This is a key transform for SPEC mpeg_audio.
// (4) Detect infinite loops; blobs of code reachable from above but not
//     below.  Several of the Code_Gen algorithms fail on such code shapes,
//     so we simply bail out.  Happens a lot in ZKM.jar, but also happens
//     from time to time in other codes (such as -Xcomp finalizer loops, etc).
//     Detection is by looking for IfNodes where only 1 projection is
//     reachable from below or CatchNodes missing some targets.
// (5) Assert for insane oop offsets in debug mode.

bool Compile::final_graph_reshaping() {
  // an infinite loop may have been eliminated by the optimizer,
  // in which case the graph will be empty.
  if (root()->req() == 1) {
    record_method_not_compilable("trivial infinite loop");
    return true;
  }

3034 3035 3036 3037 3038 3039 3040 3041 3042
  // Expensive nodes have their control input set to prevent the GVN
  // from freely commoning them. There's no GVN beyond this point so
  // no need to keep the control input. We want the expensive nodes to
  // be freely moved to the least frequent code path by gcm.
  assert(OptimizeExpensiveOps || expensive_count() == 0, "optimization off but list non empty?");
  for (int i = 0; i < expensive_count(); i++) {
    _expensive_nodes->at(i)->set_req(0, NULL);
  }

3043
  Final_Reshape_Counts frc;
D
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3044 3045 3046 3047

  // Visit everybody reachable!
  // Allocate stack of size C->unique()/2 to avoid frequent realloc
  Node_Stack nstack(unique() >> 1);
3048
  final_graph_reshaping_walk(nstack, root(), frc);
D
duke 已提交
3049 3050

  // Check for unreachable (from below) code (i.e., infinite loops).
3051 3052
  for( uint i = 0; i < frc._tests.size(); i++ ) {
    MultiBranchNode *n = frc._tests[i]->as_MultiBranch();
3053
    // Get number of CFG targets.
D
duke 已提交
3054
    // Note that PCTables include exception targets after calls.
3055 3056
    uint required_outcnt = n->required_outcnt();
    if (n->outcnt() != required_outcnt) {
D
duke 已提交
3057 3058 3059 3060 3061 3062
      // Check for a few special cases.  Rethrow Nodes never take the
      // 'fall-thru' path, so expected kids is 1 less.
      if (n->is_PCTable() && n->in(0) && n->in(0)->in(0)) {
        if (n->in(0)->in(0)->is_Call()) {
          CallNode *call = n->in(0)->in(0)->as_Call();
          if (call->entry_point() == OptoRuntime::rethrow_stub()) {
3063
            required_outcnt--;      // Rethrow always has 1 less kid
D
duke 已提交
3064 3065 3066 3067 3068 3069 3070 3071 3072
          } else if (call->req() > TypeFunc::Parms &&
                     call->is_CallDynamicJava()) {
            // Check for null receiver. In such case, the optimizer has
            // detected that the virtual call will always result in a null
            // pointer exception. The fall-through projection of this CatchNode
            // will not be populated.
            Node *arg0 = call->in(TypeFunc::Parms);
            if (arg0->is_Type() &&
                arg0->as_Type()->type()->higher_equal(TypePtr::NULL_PTR)) {
3073
              required_outcnt--;
D
duke 已提交
3074 3075 3076 3077 3078 3079 3080 3081 3082 3083
            }
          } else if (call->entry_point() == OptoRuntime::new_array_Java() &&
                     call->req() > TypeFunc::Parms+1 &&
                     call->is_CallStaticJava()) {
            // Check for negative array length. In such case, the optimizer has
            // detected that the allocation attempt will always result in an
            // exception. There is no fall-through projection of this CatchNode .
            Node *arg1 = call->in(TypeFunc::Parms+1);
            if (arg1->is_Type() &&
                arg1->as_Type()->type()->join(TypeInt::POS)->empty()) {
3084
              required_outcnt--;
D
duke 已提交
3085 3086 3087 3088
            }
          }
        }
      }
3089 3090
      // Recheck with a better notion of 'required_outcnt'
      if (n->outcnt() != required_outcnt) {
D
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3091 3092 3093 3094 3095 3096 3097
        record_method_not_compilable("malformed control flow");
        return true;            // Not all targets reachable!
      }
    }
    // Check that I actually visited all kids.  Unreached kids
    // must be infinite loops.
    for (DUIterator_Fast jmax, j = n->fast_outs(jmax); j < jmax; j++)
3098
      if (!frc._visited.test(n->fast_out(j)->_idx)) {
D
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3099 3100 3101 3102 3103 3104 3105
        record_method_not_compilable("infinite loop");
        return true;            // Found unvisited kid; must be unreach
      }
  }

  // If original bytecodes contained a mixture of floats and doubles
  // check if the optimizer has made it homogenous, item (3).
3106
  if( Use24BitFPMode && Use24BitFP && UseSSE == 0 &&
3107 3108 3109
      frc.get_float_count() > 32 &&
      frc.get_double_count() == 0 &&
      (10 * frc.get_call_count() < frc.get_float_count()) ) {
D
duke 已提交
3110 3111 3112
    set_24_bit_selection_and_mode( false,  true );
  }

3113 3114
  set_java_calls(frc.get_java_call_count());
  set_inner_loops(frc.get_inner_loop_count());
D
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3115 3116 3117 3118 3119 3120 3121 3122 3123 3124 3125 3126 3127 3128 3129 3130 3131 3132 3133 3134 3135 3136 3137 3138 3139 3140 3141 3142 3143 3144 3145 3146 3147 3148 3149 3150 3151 3152 3153 3154 3155 3156 3157 3158 3159 3160 3161 3162 3163 3164 3165 3166 3167 3168 3169 3170 3171 3172 3173 3174 3175 3176 3177 3178 3179 3180 3181 3182 3183 3184 3185 3186 3187 3188 3189 3190 3191 3192 3193 3194 3195 3196 3197 3198 3199 3200 3201 3202 3203 3204 3205 3206 3207 3208 3209 3210 3211 3212 3213 3214 3215 3216 3217 3218 3219 3220 3221 3222 3223 3224 3225 3226 3227 3228 3229 3230 3231 3232 3233 3234 3235 3236 3237 3238 3239 3240 3241 3242 3243 3244 3245 3246 3247 3248 3249 3250 3251 3252 3253 3254 3255 3256 3257 3258 3259 3260 3261 3262 3263 3264 3265 3266

  // No infinite loops, no reason to bail out.
  return false;
}

//-----------------------------too_many_traps----------------------------------
// Report if there are too many traps at the current method and bci.
// Return true if there was a trap, and/or PerMethodTrapLimit is exceeded.
bool Compile::too_many_traps(ciMethod* method,
                             int bci,
                             Deoptimization::DeoptReason reason) {
  ciMethodData* md = method->method_data();
  if (md->is_empty()) {
    // Assume the trap has not occurred, or that it occurred only
    // because of a transient condition during start-up in the interpreter.
    return false;
  }
  if (md->has_trap_at(bci, reason) != 0) {
    // Assume PerBytecodeTrapLimit==0, for a more conservative heuristic.
    // Also, if there are multiple reasons, or if there is no per-BCI record,
    // assume the worst.
    if (log())
      log()->elem("observe trap='%s' count='%d'",
                  Deoptimization::trap_reason_name(reason),
                  md->trap_count(reason));
    return true;
  } else {
    // Ignore method/bci and see if there have been too many globally.
    return too_many_traps(reason, md);
  }
}

// Less-accurate variant which does not require a method and bci.
bool Compile::too_many_traps(Deoptimization::DeoptReason reason,
                             ciMethodData* logmd) {
 if (trap_count(reason) >= (uint)PerMethodTrapLimit) {
    // Too many traps globally.
    // Note that we use cumulative trap_count, not just md->trap_count.
    if (log()) {
      int mcount = (logmd == NULL)? -1: (int)logmd->trap_count(reason);
      log()->elem("observe trap='%s' count='0' mcount='%d' ccount='%d'",
                  Deoptimization::trap_reason_name(reason),
                  mcount, trap_count(reason));
    }
    return true;
  } else {
    // The coast is clear.
    return false;
  }
}

//--------------------------too_many_recompiles--------------------------------
// Report if there are too many recompiles at the current method and bci.
// Consults PerBytecodeRecompilationCutoff and PerMethodRecompilationCutoff.
// Is not eager to return true, since this will cause the compiler to use
// Action_none for a trap point, to avoid too many recompilations.
bool Compile::too_many_recompiles(ciMethod* method,
                                  int bci,
                                  Deoptimization::DeoptReason reason) {
  ciMethodData* md = method->method_data();
  if (md->is_empty()) {
    // Assume the trap has not occurred, or that it occurred only
    // because of a transient condition during start-up in the interpreter.
    return false;
  }
  // Pick a cutoff point well within PerBytecodeRecompilationCutoff.
  uint bc_cutoff = (uint) PerBytecodeRecompilationCutoff / 8;
  uint m_cutoff  = (uint) PerMethodRecompilationCutoff / 2 + 1;  // not zero
  Deoptimization::DeoptReason per_bc_reason
    = Deoptimization::reason_recorded_per_bytecode_if_any(reason);
  if ((per_bc_reason == Deoptimization::Reason_none
       || md->has_trap_at(bci, reason) != 0)
      // The trap frequency measure we care about is the recompile count:
      && md->trap_recompiled_at(bci)
      && md->overflow_recompile_count() >= bc_cutoff) {
    // Do not emit a trap here if it has already caused recompilations.
    // Also, if there are multiple reasons, or if there is no per-BCI record,
    // assume the worst.
    if (log())
      log()->elem("observe trap='%s recompiled' count='%d' recompiles2='%d'",
                  Deoptimization::trap_reason_name(reason),
                  md->trap_count(reason),
                  md->overflow_recompile_count());
    return true;
  } else if (trap_count(reason) != 0
             && decompile_count() >= m_cutoff) {
    // Too many recompiles globally, and we have seen this sort of trap.
    // Use cumulative decompile_count, not just md->decompile_count.
    if (log())
      log()->elem("observe trap='%s' count='%d' mcount='%d' decompiles='%d' mdecompiles='%d'",
                  Deoptimization::trap_reason_name(reason),
                  md->trap_count(reason), trap_count(reason),
                  md->decompile_count(), decompile_count());
    return true;
  } else {
    // The coast is clear.
    return false;
  }
}


#ifndef PRODUCT
//------------------------------verify_graph_edges---------------------------
// Walk the Graph and verify that there is a one-to-one correspondence
// between Use-Def edges and Def-Use edges in the graph.
void Compile::verify_graph_edges(bool no_dead_code) {
  if (VerifyGraphEdges) {
    ResourceArea *area = Thread::current()->resource_area();
    Unique_Node_List visited(area);
    // Call recursive graph walk to check edges
    _root->verify_edges(visited);
    if (no_dead_code) {
      // Now make sure that no visited node is used by an unvisited node.
      bool dead_nodes = 0;
      Unique_Node_List checked(area);
      while (visited.size() > 0) {
        Node* n = visited.pop();
        checked.push(n);
        for (uint i = 0; i < n->outcnt(); i++) {
          Node* use = n->raw_out(i);
          if (checked.member(use))  continue;  // already checked
          if (visited.member(use))  continue;  // already in the graph
          if (use->is_Con())        continue;  // a dead ConNode is OK
          // At this point, we have found a dead node which is DU-reachable.
          if (dead_nodes++ == 0)
            tty->print_cr("*** Dead nodes reachable via DU edges:");
          use->dump(2);
          tty->print_cr("---");
          checked.push(use);  // No repeats; pretend it is now checked.
        }
      }
      assert(dead_nodes == 0, "using nodes must be reachable from root");
    }
  }
}
#endif

// The Compile object keeps track of failure reasons separately from the ciEnv.
// This is required because there is not quite a 1-1 relation between the
// ciEnv and its compilation task and the Compile object.  Note that one
// ciEnv might use two Compile objects, if C2Compiler::compile_method decides
// to backtrack and retry without subsuming loads.  Other than this backtracking
// behavior, the Compile's failure reason is quietly copied up to the ciEnv
// by the logic in C2Compiler.
void Compile::record_failure(const char* reason) {
  if (log() != NULL) {
    log()->elem("failure reason='%s' phase='compile'", reason);
  }
  if (_failure_reason == NULL) {
    // Record the first failure reason.
    _failure_reason = reason;
  }
3267 3268 3269
  if (!C->failure_reason_is(C2Compiler::retry_no_subsuming_loads())) {
    C->print_method(_failure_reason);
  }
D
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3270 3271 3272 3273
  _root = NULL;  // flush the graph, too
}

Compile::TracePhase::TracePhase(const char* name, elapsedTimer* accumulator, bool dolog)
3274 3275
  : TraceTime(NULL, accumulator, false NOT_PRODUCT( || TimeCompiler ), false),
    _phase_name(name), _dolog(dolog)
D
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3276 3277 3278 3279 3280 3281 3282 3283 3284
{
  if (dolog) {
    C = Compile::current();
    _log = C->log();
  } else {
    C = NULL;
    _log = NULL;
  }
  if (_log != NULL) {
3285
    _log->begin_head("phase name='%s' nodes='%d' live='%d'", _phase_name, C->unique(), C->live_nodes());
D
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3286 3287 3288 3289 3290 3291
    _log->stamp();
    _log->end_head();
  }
}

Compile::TracePhase::~TracePhase() {
3292 3293 3294 3295 3296 3297 3298 3299 3300 3301 3302 3303 3304 3305 3306 3307 3308 3309 3310

  C = Compile::current();
  if (_dolog) {
    _log = C->log();
  } else {
    _log = NULL;
  }

#ifdef ASSERT
  if (PrintIdealNodeCount) {
    tty->print_cr("phase name='%s' nodes='%d' live='%d' live_graph_walk='%d'",
                  _phase_name, C->unique(), C->live_nodes(), C->count_live_nodes_by_graph_walk());
  }

  if (VerifyIdealNodeCount) {
    Compile::current()->print_missing_nodes();
  }
#endif

D
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3311
  if (_log != NULL) {
3312
    _log->done("phase name='%s' nodes='%d' live='%d'", _phase_name, C->unique(), C->live_nodes());
D
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3313 3314
  }
}
3315 3316 3317 3318 3319 3320 3321 3322

//=============================================================================
// Two Constant's are equal when the type and the value are equal.
bool Compile::Constant::operator==(const Constant& other) {
  if (type()          != other.type()         )  return false;
  if (can_be_reused() != other.can_be_reused())  return false;
  // For floating point values we compare the bit pattern.
  switch (type()) {
3323
  case T_FLOAT:   return (_v._value.i == other._v._value.i);
3324
  case T_LONG:
3325
  case T_DOUBLE:  return (_v._value.j == other._v._value.j);
3326
  case T_OBJECT:
3327 3328
  case T_ADDRESS: return (_v._value.l == other._v._value.l);
  case T_VOID:    return (_v._value.l == other._v._value.l);  // jump-table entries
3329
  case T_METADATA: return (_v._metadata == other._v._metadata);
3330 3331 3332 3333 3334 3335 3336 3337 3338 3339
  default: ShouldNotReachHere();
  }
  return false;
}

static int type_to_size_in_bytes(BasicType t) {
  switch (t) {
  case T_LONG:    return sizeof(jlong  );
  case T_FLOAT:   return sizeof(jfloat );
  case T_DOUBLE:  return sizeof(jdouble);
3340
  case T_METADATA: return sizeof(Metadata*);
3341
    // We use T_VOID as marker for jump-table entries (labels) which
3342
    // need an internal word relocation.
3343 3344 3345 3346 3347 3348 3349 3350 3351
  case T_VOID:
  case T_ADDRESS:
  case T_OBJECT:  return sizeof(jobject);
  }

  ShouldNotReachHere();
  return -1;
}

3352 3353 3354 3355 3356 3357 3358
int Compile::ConstantTable::qsort_comparator(Constant* a, Constant* b) {
  // sort descending
  if (a->freq() > b->freq())  return -1;
  if (a->freq() < b->freq())  return  1;
  return 0;
}

3359
void Compile::ConstantTable::calculate_offsets_and_size() {
3360 3361
  // First, sort the array by frequencies.
  _constants.sort(qsort_comparator);
3362

3363 3364 3365 3366 3367 3368 3369 3370 3371 3372 3373 3374
#ifdef ASSERT
  // Make sure all jump-table entries were sorted to the end of the
  // array (they have a negative frequency).
  bool found_void = false;
  for (int i = 0; i < _constants.length(); i++) {
    Constant con = _constants.at(i);
    if (con.type() == T_VOID)
      found_void = true;  // jump-tables
    else
      assert(!found_void, "wrong sorting");
  }
#endif
3375

3376 3377 3378
  int offset = 0;
  for (int i = 0; i < _constants.length(); i++) {
    Constant* con = _constants.adr_at(i);
3379

3380 3381 3382 3383
    // Align offset for type.
    int typesize = type_to_size_in_bytes(con->type());
    offset = align_size_up(offset, typesize);
    con->set_offset(offset);   // set constant's offset
3384

3385 3386 3387 3388 3389
    if (con->type() == T_VOID) {
      MachConstantNode* n = (MachConstantNode*) con->get_jobject();
      offset = offset + typesize * n->outcnt();  // expand jump-table
    } else {
      offset = offset + typesize;
3390 3391 3392 3393 3394 3395
    }
  }

  // Align size up to the next section start (which is insts; see
  // CodeBuffer::align_at_start).
  assert(_size == -1, "already set?");
3396
  _size = align_size_up(offset, CodeEntryAlignment);
3397 3398 3399 3400
}

void Compile::ConstantTable::emit(CodeBuffer& cb) {
  MacroAssembler _masm(&cb);
3401 3402 3403 3404 3405 3406 3407 3408 3409 3410 3411 3412 3413 3414 3415 3416 3417 3418 3419 3420 3421 3422 3423 3424 3425 3426 3427 3428 3429 3430
  for (int i = 0; i < _constants.length(); i++) {
    Constant con = _constants.at(i);
    address constant_addr;
    switch (con.type()) {
    case T_LONG:   constant_addr = _masm.long_constant(  con.get_jlong()  ); break;
    case T_FLOAT:  constant_addr = _masm.float_constant( con.get_jfloat() ); break;
    case T_DOUBLE: constant_addr = _masm.double_constant(con.get_jdouble()); break;
    case T_OBJECT: {
      jobject obj = con.get_jobject();
      int oop_index = _masm.oop_recorder()->find_index(obj);
      constant_addr = _masm.address_constant((address) obj, oop_Relocation::spec(oop_index));
      break;
    }
    case T_ADDRESS: {
      address addr = (address) con.get_jobject();
      constant_addr = _masm.address_constant(addr);
      break;
    }
    // We use T_VOID as marker for jump-table entries (labels) which
    // need an internal word relocation.
    case T_VOID: {
      MachConstantNode* n = (MachConstantNode*) con.get_jobject();
      // Fill the jump-table with a dummy word.  The real value is
      // filled in later in fill_jump_table.
      address dummy = (address) n;
      constant_addr = _masm.address_constant(dummy);
      // Expand jump-table
      for (uint i = 1; i < n->outcnt(); i++) {
        address temp_addr = _masm.address_constant(dummy + i);
        assert(temp_addr, "consts section too small");
3431
      }
3432 3433
      break;
    }
3434 3435 3436 3437 3438 3439
    case T_METADATA: {
      Metadata* obj = con.get_metadata();
      int metadata_index = _masm.oop_recorder()->find_index(obj);
      constant_addr = _masm.address_constant((address) obj, metadata_Relocation::spec(metadata_index));
      break;
    }
3440
    default: ShouldNotReachHere();
3441
    }
3442
    assert(constant_addr, "consts section too small");
3443
    assert((constant_addr - _masm.code()->consts()->start()) == con.offset(), err_msg_res("must be: %d == %d", constant_addr - _masm.code()->consts()->start(), con.offset()));
3444 3445 3446 3447 3448 3449 3450 3451 3452 3453 3454 3455 3456 3457 3458
  }
}

int Compile::ConstantTable::find_offset(Constant& con) const {
  int idx = _constants.find(con);
  assert(idx != -1, "constant must be in constant table");
  int offset = _constants.at(idx).offset();
  assert(offset != -1, "constant table not emitted yet?");
  return offset;
}

void Compile::ConstantTable::add(Constant& con) {
  if (con.can_be_reused()) {
    int idx = _constants.find(con);
    if (idx != -1 && _constants.at(idx).can_be_reused()) {
3459
      _constants.adr_at(idx)->inc_freq(con.freq());  // increase the frequency by the current value
3460 3461 3462 3463 3464 3465
      return;
    }
  }
  (void) _constants.append(con);
}

3466 3467 3468
Compile::Constant Compile::ConstantTable::add(MachConstantNode* n, BasicType type, jvalue value) {
  Block* b = Compile::current()->cfg()->_bbs[n->_idx];
  Constant con(type, value, b->_freq);
3469 3470 3471 3472
  add(con);
  return con;
}

3473 3474 3475 3476 3477 3478
Compile::Constant Compile::ConstantTable::add(Metadata* metadata) {
  Constant con(metadata);
  add(con);
  return con;
}

3479
Compile::Constant Compile::ConstantTable::add(MachConstantNode* n, MachOper* oper) {
3480 3481 3482 3483 3484 3485 3486 3487
  jvalue value;
  BasicType type = oper->type()->basic_type();
  switch (type) {
  case T_LONG:    value.j = oper->constantL(); break;
  case T_FLOAT:   value.f = oper->constantF(); break;
  case T_DOUBLE:  value.d = oper->constantD(); break;
  case T_OBJECT:
  case T_ADDRESS: value.l = (jobject) oper->constant(); break;
3488 3489
  case T_METADATA: return add((Metadata*)oper->constant()); break;
  default: guarantee(false, err_msg_res("unhandled type: %s", type2name(type)));
3490
  }
3491
  return add(n, type, value);
3492 3493
}

3494
Compile::Constant Compile::ConstantTable::add_jump_table(MachConstantNode* n) {
3495 3496 3497 3498 3499 3500
  jvalue value;
  // We can use the node pointer here to identify the right jump-table
  // as this method is called from Compile::Fill_buffer right before
  // the MachNodes are emitted and the jump-table is filled (means the
  // MachNode pointers do not change anymore).
  value.l = (jobject) n;
3501 3502
  Constant con(T_VOID, value, next_jump_table_freq(), false);  // Labels of a jump-table cannot be reused.
  add(con);
3503 3504 3505 3506 3507 3508 3509 3510
  return con;
}

void Compile::ConstantTable::fill_jump_table(CodeBuffer& cb, MachConstantNode* n, GrowableArray<Label*> labels) const {
  // If called from Compile::scratch_emit_size do nothing.
  if (Compile::current()->in_scratch_emit_size())  return;

  assert(labels.is_nonempty(), "must be");
3511
  assert((uint) labels.length() == n->outcnt(), err_msg_res("must be equal: %d == %d", labels.length(), n->outcnt()));
3512 3513 3514 3515 3516 3517 3518 3519 3520

  // Since MachConstantNode::constant_offset() also contains
  // table_base_offset() we need to subtract the table_base_offset()
  // to get the plain offset into the constant table.
  int offset = n->constant_offset() - table_base_offset();

  MacroAssembler _masm(&cb);
  address* jump_table_base = (address*) (_masm.code()->consts()->start() + offset);

3521
  for (uint i = 0; i < n->outcnt(); i++) {
3522
    address* constant_addr = &jump_table_base[i];
3523
    assert(*constant_addr == (((address) n) + i), err_msg_res("all jump-table entries must contain adjusted node pointer: " INTPTR_FORMAT " == " INTPTR_FORMAT, *constant_addr, (((address) n) + i)));
3524 3525 3526 3527
    *constant_addr = cb.consts()->target(*labels.at(i), (address) constant_addr);
    cb.consts()->relocate((address) constant_addr, relocInfo::internal_word_type);
  }
}
3528 3529

void Compile::dump_inlining() {
3530
  if (PrintInlining || PrintIntrinsics NOT_PRODUCT( || PrintOptoInlining)) {
R
roland 已提交
3531 3532 3533 3534 3535 3536 3537 3538 3539 3540 3541 3542 3543 3544 3545 3546 3547 3548 3549 3550 3551 3552
    // Print inlining message for candidates that we couldn't inline
    // for lack of space or non constant receiver
    for (int i = 0; i < _late_inlines.length(); i++) {
      CallGenerator* cg = _late_inlines.at(i);
      cg->print_inlining_late("live nodes > LiveNodeCountInliningCutoff");
    }
    Unique_Node_List useful;
    useful.push(root());
    for (uint next = 0; next < useful.size(); ++next) {
      Node* n  = useful.at(next);
      if (n->is_Call() && n->as_Call()->generator() != NULL && n->as_Call()->generator()->call_node() == n) {
        CallNode* call = n->as_Call();
        CallGenerator* cg = call->generator();
        cg->print_inlining_late("receiver not constant");
      }
      uint max = n->len();
      for ( uint i = 0; i < max; ++i ) {
        Node *m = n->in(i);
        if ( m == NULL ) continue;
        useful.push(m);
      }
    }
3553 3554 3555 3556 3557
    for (int i = 0; i < _print_inlining_list->length(); i++) {
      tty->print(_print_inlining_list->at(i).ss()->as_string());
    }
  }
}
3558 3559 3560 3561 3562 3563 3564 3565 3566 3567 3568 3569 3570 3571 3572 3573 3574 3575 3576 3577 3578 3579 3580 3581 3582 3583 3584 3585 3586 3587 3588 3589 3590 3591 3592 3593 3594 3595 3596 3597 3598 3599 3600 3601 3602 3603 3604 3605 3606 3607 3608 3609 3610 3611 3612 3613 3614 3615 3616 3617 3618 3619 3620 3621 3622 3623 3624 3625 3626 3627 3628 3629 3630 3631 3632 3633 3634 3635 3636 3637 3638 3639 3640 3641 3642 3643 3644 3645 3646 3647 3648 3649 3650 3651 3652 3653 3654 3655 3656 3657 3658 3659 3660 3661 3662 3663 3664 3665 3666 3667 3668 3669 3670 3671 3672 3673 3674 3675 3676 3677 3678 3679 3680

int Compile::cmp_expensive_nodes(Node* n1, Node* n2) {
  if (n1->Opcode() < n2->Opcode())      return -1;
  else if (n1->Opcode() > n2->Opcode()) return 1;

  assert(n1->req() == n2->req(), err_msg_res("can't compare %s nodes: n1->req() = %d, n2->req() = %d", NodeClassNames[n1->Opcode()], n1->req(), n2->req()));
  for (uint i = 1; i < n1->req(); i++) {
    if (n1->in(i) < n2->in(i))      return -1;
    else if (n1->in(i) > n2->in(i)) return 1;
  }

  return 0;
}

int Compile::cmp_expensive_nodes(Node** n1p, Node** n2p) {
  Node* n1 = *n1p;
  Node* n2 = *n2p;

  return cmp_expensive_nodes(n1, n2);
}

void Compile::sort_expensive_nodes() {
  if (!expensive_nodes_sorted()) {
    _expensive_nodes->sort(cmp_expensive_nodes);
  }
}

bool Compile::expensive_nodes_sorted() const {
  for (int i = 1; i < _expensive_nodes->length(); i++) {
    if (cmp_expensive_nodes(_expensive_nodes->adr_at(i), _expensive_nodes->adr_at(i-1)) < 0) {
      return false;
    }
  }
  return true;
}

bool Compile::should_optimize_expensive_nodes(PhaseIterGVN &igvn) {
  if (_expensive_nodes->length() == 0) {
    return false;
  }

  assert(OptimizeExpensiveOps, "optimization off?");

  // Take this opportunity to remove dead nodes from the list
  int j = 0;
  for (int i = 0; i < _expensive_nodes->length(); i++) {
    Node* n = _expensive_nodes->at(i);
    if (!n->is_unreachable(igvn)) {
      assert(n->is_expensive(), "should be expensive");
      _expensive_nodes->at_put(j, n);
      j++;
    }
  }
  _expensive_nodes->trunc_to(j);

  // Then sort the list so that similar nodes are next to each other
  // and check for at least two nodes of identical kind with same data
  // inputs.
  sort_expensive_nodes();

  for (int i = 0; i < _expensive_nodes->length()-1; i++) {
    if (cmp_expensive_nodes(_expensive_nodes->adr_at(i), _expensive_nodes->adr_at(i+1)) == 0) {
      return true;
    }
  }

  return false;
}

void Compile::cleanup_expensive_nodes(PhaseIterGVN &igvn) {
  if (_expensive_nodes->length() == 0) {
    return;
  }

  assert(OptimizeExpensiveOps, "optimization off?");

  // Sort to bring similar nodes next to each other and clear the
  // control input of nodes for which there's only a single copy.
  sort_expensive_nodes();

  int j = 0;
  int identical = 0;
  int i = 0;
  for (; i < _expensive_nodes->length()-1; i++) {
    assert(j <= i, "can't write beyond current index");
    if (_expensive_nodes->at(i)->Opcode() == _expensive_nodes->at(i+1)->Opcode()) {
      identical++;
      _expensive_nodes->at_put(j++, _expensive_nodes->at(i));
      continue;
    }
    if (identical > 0) {
      _expensive_nodes->at_put(j++, _expensive_nodes->at(i));
      identical = 0;
    } else {
      Node* n = _expensive_nodes->at(i);
      igvn.hash_delete(n);
      n->set_req(0, NULL);
      igvn.hash_insert(n);
    }
  }
  if (identical > 0) {
    _expensive_nodes->at_put(j++, _expensive_nodes->at(i));
  } else if (_expensive_nodes->length() >= 1) {
    Node* n = _expensive_nodes->at(i);
    igvn.hash_delete(n);
    n->set_req(0, NULL);
    igvn.hash_insert(n);
  }
  _expensive_nodes->trunc_to(j);
}

void Compile::add_expensive_node(Node * n) {
  assert(!_expensive_nodes->contains(n), "duplicate entry in expensive list");
  assert(n->is_expensive(), "expensive nodes with non-null control here only");
  assert(!n->is_CFG() && !n->is_Mem(), "no cfg or memory nodes here");
  if (OptimizeExpensiveOps) {
    _expensive_nodes->append(n);
  } else {
    // Clear control input and let IGVN optimize expensive nodes if
    // OptimizeExpensiveOps is off.
    n->set_req(0, NULL);
  }
}
3681 3682 3683 3684 3685 3686 3687 3688 3689 3690 3691 3692 3693 3694 3695 3696 3697 3698 3699 3700 3701 3702 3703 3704 3705 3706 3707 3708 3709 3710 3711 3712 3713 3714 3715

// Auxiliary method to support randomized stressing/fuzzing.
//
// This method can be called the arbitrary number of times, with current count
// as the argument. The logic allows selecting a single candidate from the
// running list of candidates as follows:
//    int count = 0;
//    Cand* selected = null;
//    while(cand = cand->next()) {
//      if (randomized_select(++count)) {
//        selected = cand;
//      }
//    }
//
// Including count equalizes the chances any candidate is "selected".
// This is useful when we don't have the complete list of candidates to choose
// from uniformly. In this case, we need to adjust the randomicity of the
// selection, or else we will end up biasing the selection towards the latter
// candidates.
//
// Quick back-envelope calculation shows that for the list of n candidates
// the equal probability for the candidate to persist as "best" can be
// achieved by replacing it with "next" k-th candidate with the probability
// of 1/k. It can be easily shown that by the end of the run, the
// probability for any candidate is converged to 1/n, thus giving the
// uniform distribution among all the candidates.
//
// We don't care about the domain size as long as (RANDOMIZED_DOMAIN / count) is large.
#define RANDOMIZED_DOMAIN_POW 29
#define RANDOMIZED_DOMAIN (1 << RANDOMIZED_DOMAIN_POW)
#define RANDOMIZED_DOMAIN_MASK ((1 << (RANDOMIZED_DOMAIN_POW + 1)) - 1)
bool Compile::randomized_select(int count) {
  assert(count > 0, "only positive");
  return (os::random() & RANDOMIZED_DOMAIN_MASK) < (RANDOMIZED_DOMAIN / count);
}