src/share/vm/opto/indexSet.hpp - platform/external/jetbrains/jdk8u_hotspot - Git at Google

 /*
  * Copyright (c) 1998, 2011, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  *
  */

 #ifndef SHARE_VM_OPTO_INDEXSET_HPP
 #define SHARE_VM_OPTO_INDEXSET_HPP

 #include "memory/allocation.hpp"
 #include "memory/resourceArea.hpp"
 #include "opto/compile.hpp"
 #include "opto/regmask.hpp"

 // This file defines the IndexSet class, a set of sparse integer indices.
 // This data structure is used by the compiler in its liveness analysis and
 // during register allocation.

 //-------------------------------- class IndexSet ----------------------------
 // An IndexSet is a piece-wise bitvector.  At the top level, we have an array
 // of pointers to bitvector chunks called BitBlocks.  Each BitBlock has a fixed
 // size and is allocated from a shared free list.  The bits which are set in
 // each BitBlock correspond to the elements of the set.

 class IndexSet : public ResourceObj {
  friend class IndexSetIterator;

  public:
   // When we allocate an IndexSet, it starts off with an array of top level block
   // pointers of a set length.  This size is intended to be large enough for the
   // majority of IndexSets.  In the cases when this size is not large enough,
   // a separately allocated array is used.

   // The length of the preallocated top level block array
   enum { preallocated_block_list_size = 16 };

   // Elements of a IndexSet get decomposed into three fields.  The highest order
   // bits are the block index, which tell which high level block holds the element.
   // Within that block, the word index indicates which word holds the element.
   // Finally, the bit index determines which single bit within that word indicates
   // membership of the element in the set.

   // The lengths of the index bitfields
   enum { bit_index_length = 5,
          word_index_length = 3,
          block_index_length = 8 // not used
   };

   // Derived constants used for manipulating the index bitfields
   enum {
          bit_index_offset = 0, // not used
          word_index_offset = bit_index_length,
          block_index_offset = bit_index_length + word_index_length,

          bits_per_word = 1 << bit_index_length,
          words_per_block = 1 << word_index_length,
          bits_per_block = bits_per_word * words_per_block,

          bit_index_mask = right_n_bits(bit_index_length),
          word_index_mask = right_n_bits(word_index_length)
   };

   // These routines are used for extracting the block, word, and bit index
   // from an element.
   static uint get_block_index(uint element) {
     return element >> block_index_offset;
   }
   static uint get_word_index(uint element) {
     return mask_bits(element >> word_index_offset,word_index_mask);
   }
   static uint get_bit_index(uint element) {
     return mask_bits(element,bit_index_mask);
   }

   //------------------------------ class BitBlock ----------------------------
   // The BitBlock class is a segment of a bitvector set.

   class BitBlock : public ResourceObj {
    friend class IndexSetIterator;
    friend class IndexSet;

    private:
     // All of BitBlocks fields and methods are declared private.  We limit
     // access to IndexSet and IndexSetIterator.

     // A BitBlock is composed of some number of 32 bit words.  When a BitBlock
     // is not in use by any IndexSet, it is stored on a free list.  The next field
     // is used by IndexSet to mainting this free list.

     union {
       uint32 _words[words_per_block];
       BitBlock *_next;
     } _data;

     // accessors
     uint32 *words() { return _data._words; }
     void set_next(BitBlock *next) { _data._next = next; }
     BitBlock *next() { return _data._next; }

     // Operations.  A BitBlock supports four simple operations,
     // clear(), member(), insert(), and remove().  These methods do
     // not assume that the block index has been masked out.

     void clear() {
       memset(words(), 0, sizeof(uint32) * words_per_block);
     }

     bool member(uint element) {
       uint word_index = IndexSet::get_word_index(element);
       uint bit_index = IndexSet::get_bit_index(element);

       return ((words()[word_index] & (uint32)(0x1 << bit_index)) != 0);
     }

     bool insert(uint element) {
       uint word_index = IndexSet::get_word_index(element);
       uint bit_index = IndexSet::get_bit_index(element);

       uint32 bit = (0x1 << bit_index);
       uint32 before = words()[word_index];
       words()[word_index] = before | bit;
       return ((before & bit) != 0);
     }

     bool remove(uint element) {
       uint word_index = IndexSet::get_word_index(element);
       uint bit_index = IndexSet::get_bit_index(element);

       uint32 bit = (0x1 << bit_index);
       uint32 before = words()[word_index];
       words()[word_index] = before & ~bit;
       return ((before & bit) != 0);
     }
   };

   //-------------------------- BitBlock allocation ---------------------------
  private:

   // All IndexSets share an arena from which they allocate BitBlocks.  Unused
   // BitBlocks are placed on a free list.

   // The number of BitBlocks to allocate at a time
   enum { bitblock_alloc_chunk_size = 50 };

   static Arena *arena() { return Compile::current()->indexSet_arena(); }

   static void populate_free_list();

  public:

   // Invalidate the current free BitBlock list and begin allocation
   // from a new arena.  It is essential that this method is called whenever
   // the Arena being used for BitBlock allocation is reset.
   static void reset_memory(Compile* compile, Arena *arena) {
     compile->set_indexSet_free_block_list(NULL);
     compile->set_indexSet_arena(arena);

    // This should probably be done in a static initializer
    _empty_block.clear();
   }

  private:
   friend class BitBlock;
   // A distinguished BitBlock which always remains empty.  When a new IndexSet is
   // created, all of its top level BitBlock pointers are initialized to point to
   // this.
   static BitBlock _empty_block;

   //-------------------------- Members ------------------------------------------

   // The number of elements in the set
   uint      _count;

   // Our top level array of bitvector segments
   BitBlock **_blocks;

   BitBlock  *_preallocated_block_list[preallocated_block_list_size];

   // The number of top level array entries in use
   uint       _max_blocks;

   // Our assertions need to know the maximum number allowed in the set
 #ifdef ASSERT
   uint       _max_elements;
 #endif

   // The next IndexSet on the free list (not used at same time as count)
   IndexSet *_next;

  public:
   //-------------------------- Free list operations ------------------------------
   // Individual IndexSets can be placed on a free list.  This is done in PhaseLive.

   IndexSet *next() {
 #ifdef ASSERT
     if( VerifyOpto ) {
       check_watch("removed from free list?", ((_next == NULL) ? 0 : _next->_serial_number));
     }
 #endif
     return _next;
   }

   void set_next(IndexSet *next) {
 #ifdef ASSERT
     if( VerifyOpto ) {
       check_watch("put on free list?", ((next == NULL) ? 0 : next->_serial_number));
     }
 #endif
     _next = next;
   }

  private:
   //-------------------------- Utility methods -----------------------------------

   // Get the block which holds element
   BitBlock *get_block_containing(uint element) const {
     assert(element < _max_elements, "element out of bounds");
     return _blocks[get_block_index(element)];
   }

   // Set a block in the top level array
   void set_block(uint index, BitBlock *block) {
 #ifdef ASSERT
     if( VerifyOpto )
       check_watch("set block", index);
 #endif
     _blocks[index] = block;
   }

   // Get a BitBlock from the free list
   BitBlock *alloc_block();

   // Get a BitBlock from the free list and place it in the top level array
   BitBlock *alloc_block_containing(uint element);

   // Free a block from the top level array, placing it on the free BitBlock list
   void free_block(uint i);

  public:
   //-------------------------- Primitive set operations --------------------------

   void clear() {
 #ifdef ASSERT
     if( VerifyOpto )
       check_watch("clear");
 #endif
     _count = 0;
     for (uint i = 0; i < _max_blocks; i++) {
       BitBlock *block = _blocks[i];
       if (block != &_empty_block) {
         free_block(i);
       }
     }
   }

   uint count() const { return _count; }

   bool is_empty() const { return _count == 0; }

   bool member(uint element) const {
     return get_block_containing(element)->member(element);
   }

   bool insert(uint element) {
 #ifdef ASSERT
     if( VerifyOpto )
       check_watch("insert", element);
 #endif
     if (element == 0) {
       return 0;
     }
     BitBlock *block = get_block_containing(element);
     if (block == &_empty_block) {
       block = alloc_block_containing(element);
     }
     bool present = block->insert(element);
     if (!present) {
       _count++;
     }
     return !present;
   }

   bool remove(uint element) {
 #ifdef ASSERT
     if( VerifyOpto )
       check_watch("remove", element);
 #endif

     BitBlock *block = get_block_containing(element);
     bool present = block->remove(element);
     if (present) {
       _count--;
     }
     return present;
   }

   //-------------------------- Compound set operations ------------------------
   // Compute the union of all elements of one and two which interfere
   // with the RegMask mask.  If the degree of the union becomes
   // exceeds fail_degree, the union bails out.  The underlying set is
   // cleared before the union is performed.
   uint lrg_union(uint lr1, uint lr2,
                  const uint fail_degree,
                  const class PhaseIFG *ifg,
                  const RegMask &mask);


   //------------------------- Construction, initialization -----------------------

   IndexSet() {}

   // This constructor is used for making a deep copy of a IndexSet.
   IndexSet(IndexSet *set);

   // Perform initialization on a IndexSet
   void initialize(uint max_element);

   // Initialize a IndexSet.  If the top level BitBlock array needs to be
   // allocated, do it from the proffered arena.  BitBlocks are still allocated
   // from the static Arena member.
   void initialize(uint max_element, Arena *arena);

   // Exchange two sets
   void swap(IndexSet *set);

   //-------------------------- Debugging and statistics --------------------------

 #ifndef PRODUCT
   // Output a IndexSet for debugging
   void dump() const;
 #endif

 #ifdef ASSERT
   void tally_iteration_statistics() const;

   // BitBlock allocation statistics
   static julong _alloc_new;
   static julong _alloc_total;

   // Block density statistics
   static julong _total_bits;
   static julong _total_used_blocks;
   static julong _total_unused_blocks;

   // Sanity tests
   void verify() const;

   static int _serial_count;
   int        _serial_number;

   // Check to see if the serial number of the current set is the one we're tracing.
   // If it is, print a message.
   void check_watch(const char *operation, uint operand) const {
     if (IndexSetWatch != 0) {
       if (IndexSetWatch == -1 || _serial_number == IndexSetWatch) {
         tty->print_cr("IndexSet %d : %s ( %d )", _serial_number, operation, operand);
       }
     }
   }
   void check_watch(const char *operation) const {
     if (IndexSetWatch != 0) {
       if (IndexSetWatch == -1 || _serial_number == IndexSetWatch) {
         tty->print_cr("IndexSet %d : %s", _serial_number, operation);
       }
     }
   }

  public:
   static void print_statistics();

 #endif
 };


 //-------------------------------- class IndexSetIterator --------------------
 // An iterator for IndexSets.

 class IndexSetIterator VALUE_OBJ_CLASS_SPEC {
  friend class IndexSet;

  public:

   // We walk over the bits in a word in chunks of size window_size.
   enum { window_size = 5,
          window_mask = right_n_bits(window_size),
          table_size  = (1 << window_size) };

   // For an integer of length window_size, what is the first set bit?
   static const byte _first_bit[table_size];

   // For an integer of length window_size, what is the second set bit?
   static const byte _second_bit[table_size];

  private:
   // The current word we are inspecting
   uint32                _current;

   // What element number are we currently on?
   uint                  _value;

   // The index of the next word we will inspect
   uint                  _next_word;

   // A pointer to the contents of the current block
   uint32               *_words;

   // The index of the next block we will inspect
   uint                  _next_block;

   // A pointer to the blocks in our set
   IndexSet::BitBlock **_blocks;

   // The number of blocks in the set
   uint                  _max_blocks;

   // If the iterator was created from a non-const set, we replace
   // non-canonical empty blocks with the _empty_block pointer.  If
   // _set is NULL, we do no replacement.
   IndexSet            *_set;

   // Advance to the next non-empty word and return the next
   // element in the set.
   uint advance_and_next();


  public:

   // If an iterator is built from a constant set then empty blocks
   // are not canonicalized.
   IndexSetIterator(IndexSet *set);
   IndexSetIterator(const IndexSet *set);

   // Return the next element of the set.  Return 0 when done.
   uint next() {
     uint current = _current;
     if (current != 0) {
       uint value = _value;
       while (mask_bits(current,window_mask) == 0) {
         current >>= window_size;
         value += window_size;
       }

       uint advance = _second_bit[mask_bits(current,window_mask)];
       _current = current >> advance;
       _value = value + advance;
       return value + _first_bit[mask_bits(current,window_mask)];
     } else {
       return advance_and_next();
     }
   }
 };

 #endif // SHARE_VM_OPTO_INDEXSET_HPP
	/*
	* Copyright (c) 1998, 2011, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*
	*/

	#ifndef SHARE_VM_OPTO_INDEXSET_HPP
	#define SHARE_VM_OPTO_INDEXSET_HPP

	#include "memory/allocation.hpp"
	#include "memory/resourceArea.hpp"
	#include "opto/compile.hpp"
	#include "opto/regmask.hpp"

	// This file defines the IndexSet class, a set of sparse integer indices.
	// This data structure is used by the compiler in its liveness analysis and
	// during register allocation.

	//-------------------------------- class IndexSet ----------------------------
	// An IndexSet is a piece-wise bitvector. At the top level, we have an array
	// of pointers to bitvector chunks called BitBlocks. Each BitBlock has a fixed
	// size and is allocated from a shared free list. The bits which are set in
	// each BitBlock correspond to the elements of the set.

	class IndexSet : public ResourceObj {
	friend class IndexSetIterator;

	public:
	// When we allocate an IndexSet, it starts off with an array of top level block
	// pointers of a set length. This size is intended to be large enough for the
	// majority of IndexSets. In the cases when this size is not large enough,
	// a separately allocated array is used.

	// The length of the preallocated top level block array
	enum { preallocated_block_list_size = 16 };

	// Elements of a IndexSet get decomposed into three fields. The highest order
	// bits are the block index, which tell which high level block holds the element.
	// Within that block, the word index indicates which word holds the element.
	// Finally, the bit index determines which single bit within that word indicates
	// membership of the element in the set.

	// The lengths of the index bitfields
	enum { bit_index_length = 5,
	word_index_length = 3,
	block_index_length = 8 // not used
	};

	// Derived constants used for manipulating the index bitfields
	enum {
	bit_index_offset = 0, // not used
	word_index_offset = bit_index_length,
	block_index_offset = bit_index_length + word_index_length,

	bits_per_word = 1 << bit_index_length,
	words_per_block = 1 << word_index_length,
	bits_per_block = bits_per_word * words_per_block,

	bit_index_mask = right_n_bits(bit_index_length),
	word_index_mask = right_n_bits(word_index_length)
	};

	// These routines are used for extracting the block, word, and bit index
	// from an element.
	static uint get_block_index(uint element) {
	return element >> block_index_offset;
	}
	static uint get_word_index(uint element) {
	return mask_bits(element >> word_index_offset,word_index_mask);
	}
	static uint get_bit_index(uint element) {
	return mask_bits(element,bit_index_mask);
	}

	//------------------------------ class BitBlock ----------------------------
	// The BitBlock class is a segment of a bitvector set.

	class BitBlock : public ResourceObj {
	friend class IndexSetIterator;
	friend class IndexSet;

	private:
	// All of BitBlocks fields and methods are declared private. We limit
	// access to IndexSet and IndexSetIterator.

	// A BitBlock is composed of some number of 32 bit words. When a BitBlock
	// is not in use by any IndexSet, it is stored on a free list. The next field
	// is used by IndexSet to mainting this free list.

	union {
	uint32 _words[words_per_block];
	BitBlock *_next;
	} _data;

	// accessors
	uint32 *words() { return _data._words; }
	void set_next(BitBlock *next) { _data._next = next; }
	BitBlock *next() { return _data._next; }

	// Operations. A BitBlock supports four simple operations,
	// clear(), member(), insert(), and remove(). These methods do
	// not assume that the block index has been masked out.

	void clear() {
	memset(words(), 0, sizeof(uint32) * words_per_block);
	}

	bool member(uint element) {
	uint word_index = IndexSet::get_word_index(element);
	uint bit_index = IndexSet::get_bit_index(element);

	return ((words()[word_index] & (uint32)(0x1 << bit_index)) != 0);
	}

	bool insert(uint element) {
	uint word_index = IndexSet::get_word_index(element);
	uint bit_index = IndexSet::get_bit_index(element);

	uint32 bit = (0x1 << bit_index);
	uint32 before = words()[word_index];
	words()[word_index] = before \| bit;
	return ((before & bit) != 0);
	}

	bool remove(uint element) {
	uint word_index = IndexSet::get_word_index(element);
	uint bit_index = IndexSet::get_bit_index(element);

	uint32 bit = (0x1 << bit_index);
	uint32 before = words()[word_index];
	words()[word_index] = before & ~bit;
	return ((before & bit) != 0);
	}
	};

	//-------------------------- BitBlock allocation ---------------------------
	private:

	// All IndexSets share an arena from which they allocate BitBlocks. Unused
	// BitBlocks are placed on a free list.

	// The number of BitBlocks to allocate at a time
	enum { bitblock_alloc_chunk_size = 50 };

	static Arena *arena() { return Compile::current()->indexSet_arena(); }

	static void populate_free_list();

	public:

	// Invalidate the current free BitBlock list and begin allocation
	// from a new arena. It is essential that this method is called whenever
	// the Arena being used for BitBlock allocation is reset.
	static void reset_memory(Compile* compile, Arena *arena) {
	compile->set_indexSet_free_block_list(NULL);
	compile->set_indexSet_arena(arena);

	// This should probably be done in a static initializer
	_empty_block.clear();
	}

	private:
	friend class BitBlock;
	// A distinguished BitBlock which always remains empty. When a new IndexSet is
	// created, all of its top level BitBlock pointers are initialized to point to
	// this.
	static BitBlock _empty_block;

	//-------------------------- Members ------------------------------------------

	// The number of elements in the set
	uint _count;

	// Our top level array of bitvector segments
	BitBlock **_blocks;

	BitBlock *_preallocated_block_list[preallocated_block_list_size];

	// The number of top level array entries in use
	uint _max_blocks;

	// Our assertions need to know the maximum number allowed in the set
	#ifdef ASSERT
	uint _max_elements;
	#endif

	// The next IndexSet on the free list (not used at same time as count)
	IndexSet *_next;

	public:
	//-------------------------- Free list operations ------------------------------
	// Individual IndexSets can be placed on a free list. This is done in PhaseLive.

	IndexSet *next() {
	#ifdef ASSERT
	if( VerifyOpto ) {
	check_watch("removed from free list?", ((_next == NULL) ? 0 : _next->_serial_number));
	}
	#endif
	return _next;
	}

	void set_next(IndexSet *next) {
	#ifdef ASSERT
	if( VerifyOpto ) {
	check_watch("put on free list?", ((next == NULL) ? 0 : next->_serial_number));
	}
	#endif
	_next = next;
	}

	private:
	//-------------------------- Utility methods -----------------------------------

	// Get the block which holds element
	BitBlock *get_block_containing(uint element) const {
	assert(element < _max_elements, "element out of bounds");
	return _blocks[get_block_index(element)];
	}

	// Set a block in the top level array
	void set_block(uint index, BitBlock *block) {
	#ifdef ASSERT
	if( VerifyOpto )
	check_watch("set block", index);
	#endif
	_blocks[index] = block;
	}

	// Get a BitBlock from the free list
	BitBlock *alloc_block();

	// Get a BitBlock from the free list and place it in the top level array
	BitBlock *alloc_block_containing(uint element);

	// Free a block from the top level array, placing it on the free BitBlock list
	void free_block(uint i);

	public:
	//-------------------------- Primitive set operations --------------------------

	void clear() {
	#ifdef ASSERT
	if( VerifyOpto )
	check_watch("clear");
	#endif
	_count = 0;
	for (uint i = 0; i < _max_blocks; i++) {
	BitBlock *block = _blocks[i];
	if (block != &_empty_block) {
	free_block(i);
	}
	}
	}

	uint count() const { return _count; }

	bool is_empty() const { return _count == 0; }

	bool member(uint element) const {
	return get_block_containing(element)->member(element);
	}

	bool insert(uint element) {
	#ifdef ASSERT
	if( VerifyOpto )
	check_watch("insert", element);
	#endif
	if (element == 0) {
	return 0;
	}
	BitBlock *block = get_block_containing(element);
	if (block == &_empty_block) {
	block = alloc_block_containing(element);
	}
	bool present = block->insert(element);
	if (!present) {
	_count++;
	}
	return !present;
	}

	bool remove(uint element) {
	#ifdef ASSERT
	if( VerifyOpto )
	check_watch("remove", element);
	#endif

	BitBlock *block = get_block_containing(element);
	bool present = block->remove(element);
	if (present) {
	_count--;
	}
	return present;
	}

	//-------------------------- Compound set operations ------------------------
	// Compute the union of all elements of one and two which interfere
	// with the RegMask mask. If the degree of the union becomes
	// exceeds fail_degree, the union bails out. The underlying set is
	// cleared before the union is performed.
	uint lrg_union(uint lr1, uint lr2,
	const uint fail_degree,
	const class PhaseIFG *ifg,
	const RegMask &mask);


	//------------------------- Construction, initialization -----------------------

	IndexSet() {}

	// This constructor is used for making a deep copy of a IndexSet.
	IndexSet(IndexSet *set);

	// Perform initialization on a IndexSet
	void initialize(uint max_element);

	// Initialize a IndexSet. If the top level BitBlock array needs to be
	// allocated, do it from the proffered arena. BitBlocks are still allocated
	// from the static Arena member.
	void initialize(uint max_element, Arena *arena);

	// Exchange two sets
	void swap(IndexSet *set);

	//-------------------------- Debugging and statistics --------------------------

	#ifndef PRODUCT
	// Output a IndexSet for debugging
	void dump() const;
	#endif

	#ifdef ASSERT
	void tally_iteration_statistics() const;

	// BitBlock allocation statistics
	static julong _alloc_new;
	static julong _alloc_total;

	// Block density statistics
	static julong _total_bits;
	static julong _total_used_blocks;
	static julong _total_unused_blocks;

	// Sanity tests
	void verify() const;

	static int _serial_count;
	int _serial_number;

	// Check to see if the serial number of the current set is the one we're tracing.
	// If it is, print a message.
	void check_watch(const char *operation, uint operand) const {
	if (IndexSetWatch != 0) {
	if (IndexSetWatch == -1 \|\| _serial_number == IndexSetWatch) {
	tty->print_cr("IndexSet %d : %s ( %d )", _serial_number, operation, operand);
	}
	}
	}
	void check_watch(const char *operation) const {
	if (IndexSetWatch != 0) {
	if (IndexSetWatch == -1 \|\| _serial_number == IndexSetWatch) {
	tty->print_cr("IndexSet %d : %s", _serial_number, operation);
	}
	}
	}

	public:
	static void print_statistics();

	#endif
	};


	//-------------------------------- class IndexSetIterator --------------------
	// An iterator for IndexSets.

	class IndexSetIterator VALUE_OBJ_CLASS_SPEC {
	friend class IndexSet;

	public:

	// We walk over the bits in a word in chunks of size window_size.
	enum { window_size = 5,
	window_mask = right_n_bits(window_size),
	table_size = (1 << window_size) };

	// For an integer of length window_size, what is the first set bit?
	static const byte _first_bit[table_size];

	// For an integer of length window_size, what is the second set bit?
	static const byte _second_bit[table_size];

	private:
	// The current word we are inspecting
	uint32 _current;

	// What element number are we currently on?
	uint _value;

	// The index of the next word we will inspect
	uint _next_word;

	// A pointer to the contents of the current block
	uint32 *_words;

	// The index of the next block we will inspect
	uint _next_block;

	// A pointer to the blocks in our set
	IndexSet::BitBlock **_blocks;

	// The number of blocks in the set
	uint _max_blocks;

	// If the iterator was created from a non-const set, we replace
	// non-canonical empty blocks with the _empty_block pointer. If
	// _set is NULL, we do no replacement.
	IndexSet *_set;

	// Advance to the next non-empty word and return the next
	// element in the set.
	uint advance_and_next();


	public:

	// If an iterator is built from a constant set then empty blocks
	// are not canonicalized.
	IndexSetIterator(IndexSet *set);
	IndexSetIterator(const IndexSet *set);

	// Return the next element of the set. Return 0 when done.
	uint next() {
	uint current = _current;
	if (current != 0) {
	uint value = _value;
	while (mask_bits(current,window_mask) == 0) {
	current >>= window_size;
	value += window_size;
	}

	uint advance = _second_bit[mask_bits(current,window_mask)];
	_current = current >> advance;
	_value = value + advance;
	return value + _first_bit[mask_bits(current,window_mask)];
	} else {
	return advance_and_next();
	}
	}
	};

	#endif // SHARE_VM_OPTO_INDEXSET_HPP