src/hotspot/share/classfile/compactHashtable.hpp - platform/libcore - Git at Google

 /*
  * Copyright (c) 1997, 2018, 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_CLASSFILE_COMPACTHASHTABLE_HPP
 #define SHARE_VM_CLASSFILE_COMPACTHASHTABLE_HPP

 #include "oops/array.hpp"
 #include "oops/symbol.hpp"
 #include "utilities/hashtable.hpp"


 template <
   typename K,
   typename V,
   V (*DECODE)(address base_address, u4 offset),
   bool (*EQUALS)(V value, K key, int len)
   >
 class CompactHashtable;
 class NumberSeq;
 class SimpleCompactHashtable;
 class SerializeClosure;

 // Stats for symbol tables in the CDS archive
 class CompactHashtableStats {
 public:
   int hashentry_count;
   int hashentry_bytes;
   int bucket_count;
   int bucket_bytes;
 };

 #if INCLUDE_CDS
 /////////////////////////////////////////////////////////////////////////
 //
 // The compact hash table writer. Used at dump time for writing out
 // the compact table to the shared archive.
 //
 // At dump time, the CompactHashtableWriter obtains all entries from the
 // symbol/string table and adds them to a new temporary hash table. The hash
 // table size (number of buckets) is calculated using
 // '(num_entries + bucket_size - 1) / bucket_size'. The default bucket
 // size is 4 and can be changed by -XX:SharedSymbolTableBucketSize option.
 // 4 is chosen because it produces smaller sized bucket on average for
 // faster lookup. It also has relatively small number of empty buckets and
 // good distribution of the entries.
 //
 // We use a simple hash function (hash % num_bucket) for the table.
 // The new table is compacted when written out. Please see comments
 // above the CompactHashtable class for the table layout detail. The bucket
 // offsets are written to the archive as part of the compact table. The
 // bucket offset is encoded in the low 30-bit (0-29) and the bucket type
 // (regular or compact) are encoded in bit[31, 30]. For buckets with more
 // than one entry, both hash and entry offset are written to the
 // table. For buckets with only one entry, only the entry offset is written
 // to the table and the buckets are tagged as compact in their type bits.
 // Buckets without entry are skipped from the table. Their offsets are
 // still written out for faster lookup.
 //
 class CompactHashtableWriter: public StackObj {
 public:
   class Entry {
     unsigned int _hash;
     u4 _value;

   public:
     Entry() {}
     Entry(unsigned int hash, u4 val) : _hash(hash), _value(val) {}

     u4 value() {
       return _value;
     }
     unsigned int hash() {
       return _hash;
     }

     bool operator==(const CompactHashtableWriter::Entry& other) {
       return (_value == other._value && _hash == other._hash);
     }
   }; // class CompactHashtableWriter::Entry

 private:
   int _num_entries;
   int _num_buckets;
   int _num_empty_buckets;
   int _num_value_only_buckets;
   int _num_other_buckets;
   GrowableArray<Entry>** _buckets;
   CompactHashtableStats* _stats;
   Array<u4>* _compact_buckets;
   Array<u4>* _compact_entries;

 public:
   // This is called at dump-time only
   CompactHashtableWriter(int num_buckets, CompactHashtableStats* stats);
   ~CompactHashtableWriter();

   void add(unsigned int hash, u4 value);

 private:
   void allocate_table();
   void dump_table(NumberSeq* summary);

 public:
   void dump(SimpleCompactHashtable *cht, const char* table_name);

   static int default_num_buckets(size_t num_entries) {
     return default_num_buckets((int)num_entries);
   }
   static int default_num_buckets(int num_entries) {
     int num_buckets = num_entries / SharedSymbolTableBucketSize;
     // calculation of num_buckets can result in zero buckets, we need at least one
     return (num_buckets < 1) ? 1 : num_buckets;
   }
 };
 #endif // INCLUDE_CDS

 #define REGULAR_BUCKET_TYPE       0
 #define VALUE_ONLY_BUCKET_TYPE    1
 #define TABLEEND_BUCKET_TYPE      3
 #define BUCKET_OFFSET_MASK        0x3FFFFFFF
 #define BUCKET_OFFSET(info)       ((info) & BUCKET_OFFSET_MASK)
 #define BUCKET_TYPE_SHIFT         30
 #define BUCKET_TYPE(info)         (((info) & ~BUCKET_OFFSET_MASK) >> BUCKET_TYPE_SHIFT)
 #define BUCKET_INFO(offset, type) (((type) << BUCKET_TYPE_SHIFT) | ((offset) & BUCKET_OFFSET_MASK))

 /////////////////////////////////////////////////////////////////////////////
 //
 // CompactHashtable is used to store the CDS archive's symbol/string tables.
 //
 // Because these tables are read-only (no entries can be added/deleted) at run-time
 // and tend to have large number of entries, we try to minimize the footprint
 // cost per entry.
 //
 // The CompactHashtable is split into two arrays
 //
 //   u4 buckets[num_buckets+1]; // bit[31,30]: type; bit[29-0]: offset
 //   u4 entries[<variable size>]
 //
 // The size of buckets[] is 'num_buckets + 1'. Each entry of
 // buckets[] is a 32-bit encoding of the bucket type and bucket offset,
 // with the type in the left-most 2-bit and offset in the remaining 30-bit.
 // The last entry is a special type. It contains the end of the last
 // bucket.
 //
 // There are two types of buckets, regular buckets and value_only buckets. The
 // value_only buckets have '01' in their highest 2-bit, and regular buckets have
 // '00' in their highest 2-bit.
 //
 // For normal buckets, each entry is 8 bytes in the entries[]:
 //   u4 hash;    /* symbol/string hash */
 //   union {
 //     u4 offset;  /* Symbol* sym = (Symbol*)(base_address + offset) */
 //     narrowOop str; /* String narrowOop encoding */
 //   }
 //
 //
 // For value_only buckets, each entry has only the 4-byte 'offset' in the entries[].
 //
 // Example -- note that the second bucket is a VALUE_ONLY_BUCKET_TYPE so the hash code
 //            is skipped.
 // buckets[0, 4, 5, ....]
 //         |  |  |
 //         |  |  +---+
 //         |  |      |
 //         |  +----+ |
 //         v       v v
 // entries[H,O,H,O,O,H,O,H,O.....]
 //
 // See CompactHashtable::lookup() for how the table is searched at runtime.
 // See CompactHashtableWriter::dump() for how the table is written at CDS
 // dump time.
 //
 class SimpleCompactHashtable {
 protected:
   address  _base_address;
   u4  _bucket_count;
   u4  _entry_count;
   u4* _buckets;
   u4* _entries;

 public:
   SimpleCompactHashtable() {
     _entry_count = 0;
     _bucket_count = 0;
     _buckets = 0;
     _entries = 0;
   }

   void reset() {
     _bucket_count = 0;
     _entry_count = 0;
     _buckets = 0;
     _entries = 0;
   }

   void init(address base_address, u4 entry_count, u4 bucket_count, u4* buckets, u4* entries) {
     _base_address = base_address;
     _bucket_count = bucket_count;
     _entry_count = entry_count;
     _buckets = buckets;
     _entries = entries;
   }

   // Read/Write the table's header from/to the CDS archive
   void serialize_header(SerializeClosure* soc) NOT_CDS_RETURN;

   inline bool empty() {
     return (_entry_count == 0);
   }
 };

 template <
   typename K,
   typename V,
   V (*DECODE)(address base_address, u4 offset),
   bool (*EQUALS)(V value, K key, int len)
   >
 class CompactHashtable : public SimpleCompactHashtable {
   friend class VMStructs;

   V decode(u4 offset) const {
     return DECODE(_base_address, offset);
   }

 public:
   CompactHashtable() : SimpleCompactHashtable() {}

   // Lookup a value V from the compact table using key K
   inline V lookup(K key, unsigned int hash, int len) const {
     if (_entry_count > 0) {
       int index = hash % _bucket_count;
       u4 bucket_info = _buckets[index];
       u4 bucket_offset = BUCKET_OFFSET(bucket_info);
       int bucket_type = BUCKET_TYPE(bucket_info);
       u4* entry = _entries + bucket_offset;

       if (bucket_type == VALUE_ONLY_BUCKET_TYPE) {
         V value = decode(entry[0]);
         if (EQUALS(value, key, len)) {
           return value;
         }
       } else {
         // This is a regular bucket, which has more than one
         // entries. Each entry is a pair of entry (hash, offset).
         // Seek until the end of the bucket.
         u4* entry_max = _entries + BUCKET_OFFSET(_buckets[index + 1]);
         while (entry < entry_max) {
           unsigned int h = (unsigned int)(entry[0]);
           if (h == hash) {
             V value = decode(entry[1]);
             if (EQUALS(value, key, len)) {
               return value;
             }
           }
           entry += 2;
         }
       }
     }
     return NULL;
   }

   template <class ITER>
   inline void iterate(ITER* iter) const {
     for (u4 i = 0; i < _bucket_count; i++) {
       u4 bucket_info = _buckets[i];
       u4 bucket_offset = BUCKET_OFFSET(bucket_info);
       int bucket_type = BUCKET_TYPE(bucket_info);
       u4* entry = _entries + bucket_offset;

       if (bucket_type == VALUE_ONLY_BUCKET_TYPE) {
         iter->do_value(decode(entry[0]));
       } else {
         u4*entry_max = _entries + BUCKET_OFFSET(_buckets[i + 1]);
         while (entry < entry_max) {
           iter->do_value(decode(entry[1]));
           entry += 2;
         }
       }
     }
   }
 };

 ////////////////////////////////////////////////////////////////////////
 //
 // Read/Write the contents of a hashtable textual dump (created by
 // SymbolTable::dump and StringTable::dump).
 // Because the dump file may be big (hundred of MB in extreme cases),
 // we use mmap for fast access when reading it.
 //
 class HashtableTextDump {
   int _fd;
   const char* _base;
   const char* _p;
   const char* _end;
   const char* _filename;
   size_t      _size;
   int         _prefix_type;
   int         _line_no;
 public:
   HashtableTextDump(const char* filename);
   ~HashtableTextDump();

   enum {
     SymbolPrefix = 1 << 0,
     StringPrefix = 1 << 1,
     Unknown = 1 << 2
   };

   void quit(const char* err, const char* msg);

   inline int remain() {
     return (int)(_end - _p);
   }

   void corrupted(const char *p, const char *msg);

   inline void corrupted_if(bool cond, const char *msg) {
     if (cond) {
       corrupted(_p, msg);
     }
   }

   bool skip_newline();
   int skip(char must_be_char);
   void skip_past(char c);
   void check_version(const char* ver);

   inline void get_num(char delim, int *num) {
     const char* p   = _p;
     const char* end = _end;
     u8 n = 0;

     while (p < end) {
       char c = *p++;
       if ('0' <= c && c <= '9') {
         n = n * 10 + (c - '0');
         if (n > (u8)INT_MAX) {
           corrupted(_p, "Num overflow");
         }
       } else if (c == delim) {
         _p = p;
         *num = (int)n;
         return;
       } else {
         // Not [0-9], not 'delim'
         corrupted(_p, "Unrecognized format");;
       }
     }

     corrupted(_end, "Incorrect format");
     ShouldNotReachHere();
   }

   void scan_prefix_type();
   int scan_prefix(int* utf8_length);
   int scan_string_prefix();
   int scan_symbol_prefix();

   jchar unescape(const char* from, const char* end, int count);
   void get_utf8(char* utf8_buffer, int utf8_length);
   static void put_utf8(outputStream* st, const char* utf8_string, int utf8_length);
 };

 #endif // SHARE_VM_CLASSFILE_COMPACTHASHTABLE_HPP
	/*
	* Copyright (c) 1997, 2018, 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_CLASSFILE_COMPACTHASHTABLE_HPP
	#define SHARE_VM_CLASSFILE_COMPACTHASHTABLE_HPP

	#include "oops/array.hpp"
	#include "oops/symbol.hpp"
	#include "utilities/hashtable.hpp"


	template <
	typename K,
	typename V,
	V (*DECODE)(address base_address, u4 offset),
	bool (*EQUALS)(V value, K key, int len)
	>
	class CompactHashtable;
	class NumberSeq;
	class SimpleCompactHashtable;
	class SerializeClosure;

	// Stats for symbol tables in the CDS archive
	class CompactHashtableStats {
	public:
	int hashentry_count;
	int hashentry_bytes;
	int bucket_count;
	int bucket_bytes;
	};

	#if INCLUDE_CDS
	/////////////////////////////////////////////////////////////////////////
	//
	// The compact hash table writer. Used at dump time for writing out
	// the compact table to the shared archive.
	//
	// At dump time, the CompactHashtableWriter obtains all entries from the
	// symbol/string table and adds them to a new temporary hash table. The hash
	// table size (number of buckets) is calculated using
	// '(num_entries + bucket_size - 1) / bucket_size'. The default bucket
	// size is 4 and can be changed by -XX:SharedSymbolTableBucketSize option.
	// 4 is chosen because it produces smaller sized bucket on average for
	// faster lookup. It also has relatively small number of empty buckets and
	// good distribution of the entries.
	//
	// We use a simple hash function (hash % num_bucket) for the table.
	// The new table is compacted when written out. Please see comments
	// above the CompactHashtable class for the table layout detail. The bucket
	// offsets are written to the archive as part of the compact table. The
	// bucket offset is encoded in the low 30-bit (0-29) and the bucket type
	// (regular or compact) are encoded in bit[31, 30]. For buckets with more
	// than one entry, both hash and entry offset are written to the
	// table. For buckets with only one entry, only the entry offset is written
	// to the table and the buckets are tagged as compact in their type bits.
	// Buckets without entry are skipped from the table. Their offsets are
	// still written out for faster lookup.
	//
	class CompactHashtableWriter: public StackObj {
	public:
	class Entry {
	unsigned int _hash;
	u4 _value;

	public:
	Entry() {}
	Entry(unsigned int hash, u4 val) : _hash(hash), _value(val) {}

	u4 value() {
	return _value;
	}
	unsigned int hash() {
	return _hash;
	}

	bool operator==(const CompactHashtableWriter::Entry& other) {
	return (_value == other._value && _hash == other._hash);
	}
	}; // class CompactHashtableWriter::Entry

	private:
	int _num_entries;
	int _num_buckets;
	int _num_empty_buckets;
	int _num_value_only_buckets;
	int _num_other_buckets;
	GrowableArray<Entry>** _buckets;
	CompactHashtableStats* _stats;
	Array<u4>* _compact_buckets;
	Array<u4>* _compact_entries;

	public:
	// This is called at dump-time only
	CompactHashtableWriter(int num_buckets, CompactHashtableStats* stats);
	~CompactHashtableWriter();

	void add(unsigned int hash, u4 value);

	private:
	void allocate_table();
	void dump_table(NumberSeq* summary);

	public:
	void dump(SimpleCompactHashtable cht, const char table_name);

	static int default_num_buckets(size_t num_entries) {
	return default_num_buckets((int)num_entries);
	}
	static int default_num_buckets(int num_entries) {
	int num_buckets = num_entries / SharedSymbolTableBucketSize;
	// calculation of num_buckets can result in zero buckets, we need at least one
	return (num_buckets < 1) ? 1 : num_buckets;
	}
	};
	#endif // INCLUDE_CDS

	#define REGULAR_BUCKET_TYPE 0
	#define VALUE_ONLY_BUCKET_TYPE 1
	#define TABLEEND_BUCKET_TYPE 3
	#define BUCKET_OFFSET_MASK 0x3FFFFFFF
	#define BUCKET_OFFSET(info) ((info) & BUCKET_OFFSET_MASK)
	#define BUCKET_TYPE_SHIFT 30
	#define BUCKET_TYPE(info) (((info) & ~BUCKET_OFFSET_MASK) >> BUCKET_TYPE_SHIFT)
	#define BUCKET_INFO(offset, type) (((type) << BUCKET_TYPE_SHIFT) \| ((offset) & BUCKET_OFFSET_MASK))

	/////////////////////////////////////////////////////////////////////////////
	//
	// CompactHashtable is used to store the CDS archive's symbol/string tables.
	//
	// Because these tables are read-only (no entries can be added/deleted) at run-time
	// and tend to have large number of entries, we try to minimize the footprint
	// cost per entry.
	//
	// The CompactHashtable is split into two arrays
	//
	// u4 buckets[num_buckets+1]; // bit[31,30]: type; bit[29-0]: offset
	// u4 entries[<variable size>]
	//
	// The size of buckets[] is 'num_buckets + 1'. Each entry of
	// buckets[] is a 32-bit encoding of the bucket type and bucket offset,
	// with the type in the left-most 2-bit and offset in the remaining 30-bit.
	// The last entry is a special type. It contains the end of the last
	// bucket.
	//
	// There are two types of buckets, regular buckets and value_only buckets. The
	// value_only buckets have '01' in their highest 2-bit, and regular buckets have
	// '00' in their highest 2-bit.
	//
	// For normal buckets, each entry is 8 bytes in the entries[]:
	// u4 hash; /* symbol/string hash */
	// union {
	// u4 offset; /* Symbol* sym = (Symbol)(base_address + offset) /
	// narrowOop str; /* String narrowOop encoding */
	// }
	//
	//
	// For value_only buckets, each entry has only the 4-byte 'offset' in the entries[].
	//
	// Example -- note that the second bucket is a VALUE_ONLY_BUCKET_TYPE so the hash code
	// is skipped.
	// buckets[0, 4, 5, ....]
	// \| \| \|
	// \| \| +---+
	// \| \| \|
	// \| +----+ \|
	// v v v
	// entries[H,O,H,O,O,H,O,H,O.....]
	//
	// See CompactHashtable::lookup() for how the table is searched at runtime.
	// See CompactHashtableWriter::dump() for how the table is written at CDS
	// dump time.
	//
	class SimpleCompactHashtable {
	protected:
	address _base_address;
	u4 _bucket_count;
	u4 _entry_count;
	u4* _buckets;
	u4* _entries;

	public:
	SimpleCompactHashtable() {
	_entry_count = 0;
	_bucket_count = 0;
	_buckets = 0;
	_entries = 0;
	}

	void reset() {
	_bucket_count = 0;
	_entry_count = 0;
	_buckets = 0;
	_entries = 0;
	}

	void init(address base_address, u4 entry_count, u4 bucket_count, u4* buckets, u4* entries) {
	_base_address = base_address;
	_bucket_count = bucket_count;
	_entry_count = entry_count;
	_buckets = buckets;
	_entries = entries;
	}

	// Read/Write the table's header from/to the CDS archive
	void serialize_header(SerializeClosure* soc) NOT_CDS_RETURN;

	inline bool empty() {
	return (_entry_count == 0);
	}
	};

	template <
	typename K,
	typename V,
	V (*DECODE)(address base_address, u4 offset),
	bool (*EQUALS)(V value, K key, int len)
	>
	class CompactHashtable : public SimpleCompactHashtable {
	friend class VMStructs;

	V decode(u4 offset) const {
	return DECODE(_base_address, offset);
	}

	public:
	CompactHashtable() : SimpleCompactHashtable() {}

	// Lookup a value V from the compact table using key K
	inline V lookup(K key, unsigned int hash, int len) const {
	if (_entry_count > 0) {
	int index = hash % _bucket_count;
	u4 bucket_info = _buckets[index];
	u4 bucket_offset = BUCKET_OFFSET(bucket_info);
	int bucket_type = BUCKET_TYPE(bucket_info);
	u4* entry = _entries + bucket_offset;

	if (bucket_type == VALUE_ONLY_BUCKET_TYPE) {
	V value = decode(entry[0]);
	if (EQUALS(value, key, len)) {
	return value;
	}
	} else {
	// This is a regular bucket, which has more than one
	// entries. Each entry is a pair of entry (hash, offset).
	// Seek until the end of the bucket.
	u4* entry_max = _entries + BUCKET_OFFSET(_buckets[index + 1]);
	while (entry < entry_max) {
	unsigned int h = (unsigned int)(entry[0]);
	if (h == hash) {
	V value = decode(entry[1]);
	if (EQUALS(value, key, len)) {
	return value;
	}
	}
	entry += 2;
	}
	}
	}
	return NULL;
	}

	template <class ITER>
	inline void iterate(ITER* iter) const {
	for (u4 i = 0; i < _bucket_count; i++) {
	u4 bucket_info = _buckets[i];
	u4 bucket_offset = BUCKET_OFFSET(bucket_info);
	int bucket_type = BUCKET_TYPE(bucket_info);
	u4* entry = _entries + bucket_offset;

	if (bucket_type == VALUE_ONLY_BUCKET_TYPE) {
	iter->do_value(decode(entry[0]));
	} else {
	u4*entry_max = _entries + BUCKET_OFFSET(_buckets[i + 1]);
	while (entry < entry_max) {
	iter->do_value(decode(entry[1]));
	entry += 2;
	}
	}
	}
	}
	};

	////////////////////////////////////////////////////////////////////////
	//
	// Read/Write the contents of a hashtable textual dump (created by
	// SymbolTable::dump and StringTable::dump).
	// Because the dump file may be big (hundred of MB in extreme cases),
	// we use mmap for fast access when reading it.
	//
	class HashtableTextDump {
	int _fd;
	const char* _base;
	const char* _p;
	const char* _end;
	const char* _filename;
	size_t _size;
	int _prefix_type;
	int _line_no;
	public:
	HashtableTextDump(const char* filename);
	~HashtableTextDump();

	enum {
	SymbolPrefix = 1 << 0,
	StringPrefix = 1 << 1,
	Unknown = 1 << 2
	};

	void quit(const char* err, const char* msg);

	inline int remain() {
	return (int)(_end - _p);
	}

	void corrupted(const char p, const char msg);

	inline void corrupted_if(bool cond, const char *msg) {
	if (cond) {
	corrupted(_p, msg);
	}
	}

	bool skip_newline();
	int skip(char must_be_char);
	void skip_past(char c);
	void check_version(const char* ver);

	inline void get_num(char delim, int *num) {
	const char* p = _p;
	const char* end = _end;
	u8 n = 0;

	while (p < end) {
	char c = *p++;
	if ('0' <= c && c <= '9') {
	n = n * 10 + (c - '0');
	if (n > (u8)INT_MAX) {
	corrupted(_p, "Num overflow");
	}
	} else if (c == delim) {
	_p = p;
	*num = (int)n;
	return;
	} else {
	// Not [0-9], not 'delim'
	corrupted(_p, "Unrecognized format");;
	}
	}

	corrupted(_end, "Incorrect format");
	ShouldNotReachHere();
	}

	void scan_prefix_type();
	int scan_prefix(int* utf8_length);
	int scan_string_prefix();
	int scan_symbol_prefix();

	jchar unescape(const char* from, const char* end, int count);
	void get_utf8(char* utf8_buffer, int utf8_length);
	static void put_utf8(outputStream* st, const char* utf8_string, int utf8_length);
	};

	#endif // SHARE_VM_CLASSFILE_COMPACTHASHTABLE_HPP