path: root/ace/Hash_Map_Manager_T.h

/* -*- C++ -*- */
// $Id$

// ============================================================================
//
// = LIBRARY
//    ace
//
// = FILENAME
//    Hash_Map_Manager_T.h
//
// = AUTHOR
//    Doug Schmidt
//
// ============================================================================

#ifndef ACE_HASH_MAP_MANAGER_T_H
#define ACE_HASH_MAP_MANAGER_T_H

#include "ace/OS.h"
#include "ace/Functor.h"

#if !defined (ACE_LACKS_PRAGMA_ONCE)
# pragma once
#endif /* ACE_LACKS_PRAGMA_ONCE */

template <class EXT_ID, class INT_ID>
class ACE_Hash_Map_Entry
{
  // = TITLE
  //     Define an entry in the hash table.
public:
  // = Initialization and termination methods.
  ACE_Hash_Map_Entry (const EXT_ID &ext_id,
                      const INT_ID &int_id,
                      ACE_Hash_Map_Entry<EXT_ID, INT_ID> *next = 0,
                      ACE_Hash_Map_Entry<EXT_ID, INT_ID> *prev = 0);
  // Constructor.

  ACE_Hash_Map_Entry (ACE_Hash_Map_Entry<EXT_ID, INT_ID> *next,
                      ACE_Hash_Map_Entry<EXT_ID, INT_ID> *prev);
  // Constructor.

# if ! defined (ACE_HAS_BROKEN_NOOP_DTORS)
  ~ACE_Hash_Map_Entry (void);
  // Destructor.
#endif /* ! defined (ACE_HAS_BROKEN_NOOP_DTORS) */

  EXT_ID ext_id_;
  // Key used to look up an entry.

  INT_ID int_id_;
  // The contents of the entry itself.

  ACE_Hash_Map_Entry<EXT_ID, INT_ID> *next_;
  // Pointer to the next item in the bucket of overflow nodes.

  ACE_Hash_Map_Entry<EXT_ID, INT_ID> *prev_;
  // Pointer to the prev item in the bucket of overflow nodes.

  void dump (void) const;
  // Dump the state of an object.
};

// Forward decl.
template <class EXT_ID, class INT_ID, class HASH_KEY, class COMPARE_KEYS, class ACE_LOCK>
class ACE_Hash_Map_Iterator_Base_Ex;

// Forward decl.
template <class EXT_ID, class INT_ID, class HASH_KEY, class COMPARE_KEYS, class ACE_LOCK>
class ACE_Hash_Map_Iterator_Ex;

// Forward decl.
template <class EXT_ID, class INT_ID, class HASH_KEY, class COMPARE_KEYS, class ACE_LOCK>
class ACE_Hash_Map_Reverse_Iterator_Ex;

// Forward decl.
template <class EXT_ID, class INT_ID, class HASH_KEY, class COMPARE_KEYS, class ACE_LOCK>
class ACE_Hash_Map_Bucket_Iterator;

// Forward decl.
class ACE_Allocator;

template <class EXT_ID, class INT_ID, class HASH_KEY, class COMPARE_KEYS, class ACE_LOCK>
class ACE_Hash_Map_Manager_Ex
{
  // = TITLE
  //     Define a map abstraction that efficiently associates
  //     <EXT_ID>s with <INT_ID>s.
  //
  // = DESCRIPTION
  //
  //     This implementation of a map uses a hash table.  Key hashing
  //     is achieved through the HASH_KEY object and key comparison is
  //     achieved through the COMPARE_KEYS object.
  //
  //     This class uses an <ACE_Allocator> to allocate memory.  The
  //     user can make this a persistent class by providing an
  //     <ACE_Allocator> with a persistable memory pool.
public:
  friend class ACE_Hash_Map_Iterator_Base_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK>;
  friend class ACE_Hash_Map_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK>;
  friend class ACE_Hash_Map_Reverse_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK>;
  friend class ACE_Hash_Map_Bucket_Iterator<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK>;

  typedef EXT_ID
          KEY;
  typedef INT_ID
          VALUE;
  typedef ACE_Hash_Map_Entry<EXT_ID, INT_ID>
          ENTRY;

  // = ACE-style iterator typedefs.
  typedef ACE_Hash_Map_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK>
          ITERATOR;
  typedef ACE_Hash_Map_Reverse_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK>
          REVERSE_ITERATOR;

  // = STL-style iterator typedefs.
  typedef ACE_Hash_Map_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK>
          iterator;
  typedef ACE_Hash_Map_Reverse_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK>
          reverse_iterator;

  // = Initialization and termination methods.

  ACE_Hash_Map_Manager_Ex (ACE_Allocator *alloc = 0);
  // Initialize a <Hash_Map_Manager_Ex> with default size.

  ACE_Hash_Map_Manager_Ex (size_t size,
                           ACE_Allocator *alloc = 0);
  // Initialize a <Hash_Map_Manager_Ex> with size <length>.

  int open (size_t size = ACE_DEFAULT_MAP_SIZE,
            ACE_Allocator *alloc = 0);
  // Initialize a <Hash_Map_Manager_Ex> with <size> elements.

  int close (void);
  // Close down a <Hash_Map_Manager_Ex> and release dynamically allocated
  // resources.

  ~ACE_Hash_Map_Manager_Ex (void);
  // Initialize a <Hash_Map_Manager_Ex> with size <length>.

  int bind (const EXT_ID &item,
            const INT_ID &int_id);
  // Associate <ext_id> with <int_id>.  If <ext_id> is already in the
  // map then the <ACE_Hash_Map_Entry> is not changed.  Returns 0 if a
  // new entry is bound successfully, returns 1 if an attempt is made
  // to bind an existing entry, and returns -1 if failures occur.

  int bind (const EXT_ID &ext_id,
            const INT_ID &int_id,
            ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry);
  // Same as a normal bind, except the map entry is also passed back
  // to the caller.  The entry in this case will either be the newly
  // created entry, or the existing one.

  int trybind (const EXT_ID &ext_id,
               INT_ID &int_id);
  // Associate <ext_id> with <int_id> if and only if <ext_id> is not
  // in the map.  If <ext_id> is already in the map then the <int_id>
  // parameter is assigned the existing value in the map.  Returns 0
  // if a new entry is bound successfully, returns 1 if an attempt is
  // made to bind an existing entry, and returns -1 if failures occur.

  int trybind (const EXT_ID &ext_id,
               INT_ID &int_id,
               ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry);
  // Same as a normal trybind, except the map entry is also passed
  // back to the caller.  The entry in this case will either be the
  // newly created entry, or the existing one.

  int rebind (const EXT_ID &ext_id,
              const INT_ID &int_id);
  // Reassociate <ext_id> with <int_id>.  If <ext_id> is not in the
  // map then behaves just like <bind>.  Returns 0 if a new entry is
  // bound successfully, returns 1 if an existing entry was rebound,
  // and returns -1 if failures occur.

  int rebind (const EXT_ID &ext_id,
              const INT_ID &int_id,
              ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry);
  // Same as a normal rebind, except the map entry is also passed back
  // to the caller.  The entry in this case will either be the newly
  // created entry, or the existing one.

  int rebind (const EXT_ID &ext_id,
              const INT_ID &int_id,
              INT_ID &old_int_id);
  // Associate <ext_id> with <int_id>.  If <ext_id> is not in the map
  // then behaves just like <bind>.  Otherwise, store the old value of
  // <int_id> into the "out" parameter and rebind the new parameters.
  // Returns 0 if a new entry is bound successfully, returns 1 if an
  // existing entry was rebound, and returns -1 if failures occur.

  int rebind (const EXT_ID &ext_id,
              const INT_ID &int_id,
              INT_ID &old_int_id,
              ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry);
  // Same as a normal rebind, except the map entry is also passed back
  // to the caller.  The entry in this case will either be the newly
  // created entry, or the existing one.

  int rebind (const EXT_ID &ext_id,
              const INT_ID &int_id,
              EXT_ID &old_ext_id,
              INT_ID &old_int_id);
  // Associate <ext_id> with <int_id>.  If <ext_id> is not in the map
  // then behaves just like <bind>.  Otherwise, store the old values
  // of <ext_id> and <int_id> into the "out" parameters and rebind the
  // new parameters.  This is very useful if you need to have an
  // atomic way of updating <ACE_Hash_Map_Entrys> and you also need
  // full control over memory allocation.  Returns 0 if a new entry is
  // bound successfully, returns 1 if an existing entry was rebound,
  // and returns -1 if failures occur.

  int rebind (const EXT_ID &ext_id,
              const INT_ID &int_id,
              EXT_ID &old_ext_id,
              INT_ID &old_int_id,
              ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry);
  // Same as a normal rebind, except the map entry is also passed back
  // to the caller.  The entry in this case will either be the newly
  // created entry, or the existing one.

  int find (const EXT_ID &ext_id,
            INT_ID &int_id);
  // Locate <ext_id> and pass out parameter via <int_id>.  If found,
  // return 0, returns -1 if not found.

  int find (const EXT_ID &ext_id);
  // Returns 0 if the <ext_id> is in the mapping, otherwise -1.

  int find (const EXT_ID &ext_id,
            ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry);
  // Locate <ext_id> and pass out parameter via <entry>.  If found,
  // return 0, returns -1 if not found.

  int unbind (const EXT_ID &ext_id);
  // Unbind (remove) the <ext_id> from the map.  Don't return the
  // <int_id> to the caller (this is useful for collections where the
  // <int_id>s are *not* dynamically allocated...)

  int unbind (const EXT_ID &ext_id,
              INT_ID &int_id);
  // Break any association of <ext_id>.  Returns the value of <int_id>
  // in case the caller needs to deallocate memory.

  int unbind (ACE_Hash_Map_Entry<EXT_ID, INT_ID> *entry);
  // Remove entry from map.

  size_t current_size (void) const;
  // Return the current size of the map.

  size_t total_size (void) const;
  // Return the total size of the map.

  ACE_LOCK &mutex (void);
  // Returns a reference to the underlying <ACE_LOCK>.  This makes it
  // possible to acquire the lock explicitly, which can be useful in
  // some cases if you instantiate the <ACE_Atomic_Op> with an
  // <ACE_Recursive_Mutex> or <ACE_Process_Mutex>, or if you need to
  // guard the state of an iterator.  NOTE: the right name would be
  // <lock>, but HP/C++ will choke on that!

  void dump (void) const;
  // Dump the state of an object.

  // = STL styled iterator factory functions.

  ACE_Hash_Map_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> begin (void);
  ACE_Hash_Map_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> end (void);
  // Return forward iterator.

  ACE_Hash_Map_Reverse_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> rbegin (void);
  ACE_Hash_Map_Reverse_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> rend (void);
  // Return reverse iterator.

protected:
  // = The following methods do the actual work.

  int equal (const EXT_ID &id1, const EXT_ID &id2);
  // Returns 1 if <id1> == <id2>, else 0.  This is defined as a
  // separate method to facilitate template specialization.

  u_long hash (const EXT_ID &ext_id);
  // Compute the hash value of the <ext_id>.  This is defined as a
  // separate method to facilitate template specialization.

  // = These methods assume locks are held by private methods.

  int bind_i (const EXT_ID &ext_id,
              const INT_ID &int_id);
  // Performs bind.  Must be called with locks held.

  int bind_i (const EXT_ID &ext_id,
              const INT_ID &int_id,
              ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry);
  // Performs bind.  Must be called with locks held.

  int trybind_i (const EXT_ID &ext_id,
                 INT_ID &int_id);
  // Performs trybind.  Must be called with locks held.

  int trybind_i (const EXT_ID &ext_id,
                 INT_ID &int_id,
                 ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry);
  // Performs trybind.  Must be called with locks held.

  int rebind_i (const EXT_ID &ext_id,
                const INT_ID &int_id);
  // Performs rebind.  Must be called with locks held.

  int rebind_i (const EXT_ID &ext_id,
                const INT_ID &int_id,
                ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry);
  // Performs rebind.  Must be called with locks held.

  int rebind_i (const EXT_ID &ext_id,
                const INT_ID &int_id,
                INT_ID &old_int_id);
  // Performs rebind.  Must be called with locks held.

  int rebind_i (const EXT_ID &ext_id,
                const INT_ID &int_id,
                INT_ID &old_int_id,
                ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry);
  // Performs rebind.  Must be called with locks held.

  int rebind_i (const EXT_ID &ext_id,
                const INT_ID &int_id,
                EXT_ID &old_ext_id,
                INT_ID &old_int_id);
  // Performs rebind.  Must be called with locks held.

  int rebind_i (const EXT_ID &ext_id,
                const INT_ID &int_id,
                EXT_ID &old_ext_id,
                INT_ID &old_int_id,
                ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry);
  // Performs rebind.  Must be called with locks held.

  int find_i (const EXT_ID &ext_id,
              INT_ID &int_id);
  // Performs a find of <int_id> using <ext_id> as the key.  Must be
  // called with locks held.

  int find_i (const EXT_ID &ext_id);
  // Performs a find using <ext_id> as the key.  Must be called with
  // locks held.

  int find_i (const EXT_ID &ext_id,
              ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry);
  // Performs a find using <ext_id> as the key.  Must be called with
  // locks held.

  int unbind_i (const EXT_ID &ext_id,
                INT_ID &int_id);
  // Performs unbind.  Must be called with locks held.

  int unbind_i (const EXT_ID &ext_id);
  // Performs unbind.  Must be called with locks held.

  int unbind_i (ACE_Hash_Map_Entry<EXT_ID, INT_ID> *entry);
  // Performs unbind.  Must be called with locks held.

  int create_buckets (size_t size);
  // Resize the map.  Must be called with locks held.  Note, that this
  // method should never be called more than once or else all the
  // hashing will get screwed up as the size will change.

  int close_i (void);
  // Close down a <Map_Manager_Ex>.  Must be called with
  // locks held.

  ACE_Allocator *allocator_;
  // Pointer to a memory allocator.

  ACE_LOCK lock_;
  // Synchronization variable for the MT_SAFE <ACE_Hash_Map_Manager_Ex>.

  HASH_KEY hash_key_;
  // Function object used for hashing keys.

  COMPARE_KEYS compare_keys_;
  // Function object used for comparing keys.

private:
  int shared_find (const EXT_ID &ext_id,
                   ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&entry,
                   u_long &loc);
  // Returns the <ACE_Hash_Map_Entry> that corresponds to <ext_id>.

  ACE_Hash_Map_Entry<EXT_ID, INT_ID> *table_;
  // Array of <ACE_Hash_Map_Entry> *s, each of which points to an
  // <ACE_Hash_Map_Entry> that serves as the beginning of a linked
  // list of <EXT_ID>s that hash to that bucket.

  size_t total_size_;
  // Total size of the hash table.

  size_t cur_size_;
  // Current number of entries in the table (note that this can be
  // larger than <total_size_> due to the bucket chaining).
};

template <class EXT_ID, class INT_ID, class HASH_KEY, class COMPARE_KEYS, class ACE_LOCK>
class ACE_Hash_Map_Iterator_Base_Ex
{
  // = TITLE
  //     Base iterator for the <ACE_Hash_Map_Manager_Ex>
  //
  // = DESCRIPTION
  //     This class factors out common code from its templatized
  //     subclasses.
public:
  // = Initialization method.
  ACE_Hash_Map_Iterator_Base_Ex (ACE_Hash_Map_Manager_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &mm,
                                 int head);
  // Contructor.  If head != 0, the iterator constructed is positioned
  // at the head of the map, it is positioned at the end otherwise.

  // = ITERATION methods.

  int next (ACE_Hash_Map_Entry<EXT_ID, INT_ID> *&next_entry) const;
  // Pass back the next <entry> that hasn't been seen in the Set.
  // Returns 0 when all items have been seen, else 1.

  int done (void) const;
  // Returns 1 when all items have been seen, else 0.

  ACE_Hash_Map_Entry<EXT_ID, INT_ID>& operator* (void) const;
  // Returns a reference to the interal element <this> is pointing to.

  ACE_Hash_Map_Manager_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK>& map (void);
  // Returns reference the Hash_Map_Manager_Ex that is being iterated
  // over.

  int operator== (const ACE_Hash_Map_Iterator_Base_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &) const;
  int operator!= (const ACE_Hash_Map_Iterator_Base_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &) const;
  // Check if two iterators point to the same position

  ACE_ALLOC_HOOK_DECLARE;
  // Declare the dynamic allocation hooks.

protected:
  int forward_i (void);
  // Move forward by one element in the set.  Returns 0 when there's
  // no more item in the set after the current items, else 1.

  int reverse_i (void);
  // Move backward by one element in the set.  Returns 0 when there's
  // no more item in the set before the current item, else 1.

  void dump_i (void) const;
  // Dump the state of an object.

  ACE_Hash_Map_Manager_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> *map_man_;
  // Map we are iterating over.

  ssize_t index_;
  // Keeps track of how far we've advanced in the table.

  ACE_Hash_Map_Entry<EXT_ID, INT_ID> *next_;
  // Keeps track of how far we've advanced in a linked list in each
  // table slot.
};

template <class EXT_ID, class INT_ID, class HASH_KEY, class COMPARE_KEYS, class ACE_LOCK>
class ACE_Hash_Map_Iterator_Ex : public ACE_Hash_Map_Iterator_Base_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK>
{
  // = TITLE
  //     Forward iterator for the <ACE_Hash_Map_Manager_Ex>.
  //
  // = DESCRIPTION
  //     This class does not perform any internal locking of the
  //     <ACE_Hash_Map_Manager_Ex> it is iterating upon since locking is
  //     inherently inefficient and/or error-prone within an STL-style
  //     iterator.  If you require locking, you can explicitly use an
  //     <ACE_Guard> or <ACE_Read_Guard> on the <ACE_Hash_Map_Manager_Ex>'s
  //     internal lock, which is accessible via its <mutex> method.
public:
  // = Initialization method.
  ACE_Hash_Map_Iterator_Ex (ACE_Hash_Map_Manager_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &mm,
                            int tail = 0);
  // = Iteration methods.
  int advance (void);
  // Move forward by one element in the set.  Returns 0 when all the
  // items in the set have been seen, else 1.

  void dump (void) const;
  // Dump the state of an object.

  // = STL styled iteration, compare, and reference functions.

  ACE_Hash_Map_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &operator++ (void);
  // Prefix advance.

  ACE_Hash_Map_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> operator++ (int);
  // Postfix advance.

  ACE_Hash_Map_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &operator-- (void);
  // Prefix reverse.

  ACE_Hash_Map_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> operator-- (int);
  // Postfix reverse.

  ACE_ALLOC_HOOK_DECLARE;
  // Declare the dynamic allocation hooks.
};

template <class EXT_ID, class INT_ID, class HASH_KEY, class COMPARE_KEYS, class ACE_LOCK>
class ACE_Hash_Map_Bucket_Iterator
{
  // = TITLE
  //     Forward iterator for the <ACE_Hash_Map_Manager_Ex> which only
  //     traverses a particular bucket.  The particular bucket is
  //     specified by the <EXT_ID> parameter specified in the
  //     constructor.
  //
  // = DESCRIPTION
  //     This class does not perform any internal locking of the
  //     <ACE_Hash_Map_Manager_Ex> it is iterating upon since locking
  //     is inherently inefficient and/or error-prone within an
  //     STL-style iterator.  If you require locking, you can
  //     explicitly use an <ACE_Guard> or <ACE_Read_Guard> on the
  //     <ACE_Hash_Map_Manager_Ex>'s internal lock, which is
  //     accessible via its <mutex> method.
  //
  //     Note that this iterator cannot be created by calling a method
  //     on the map, since this would require
public:
  // = Initialization method.
  ACE_Hash_Map_Bucket_Iterator (ACE_Hash_Map_Manager_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &mm,
                                const EXT_ID &ext_id,
                                int tail = 0);

  // = STL styled iteration, compare, and reference functions.

  ACE_Hash_Map_Bucket_Iterator<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &operator++ (void);
  // Prefix advance.

  ACE_Hash_Map_Bucket_Iterator<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> operator++ (int);
  // Postfix advance.

  ACE_Hash_Map_Bucket_Iterator<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &operator-- (void);
  // Prefix reverse.

  ACE_Hash_Map_Bucket_Iterator<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> operator-- (int);
  // Postfix reverse.

  ACE_Hash_Map_Entry<EXT_ID, INT_ID>& operator* (void) const;
  // Returns a reference to the interal element <this> is pointing to.

  ACE_Hash_Map_Manager_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK>& map (void);
  // Returns reference the Hash_Map_Manager_Ex that is being iterated
  // over.

  int operator== (const ACE_Hash_Map_Bucket_Iterator<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &) const;
  int operator!= (const ACE_Hash_Map_Bucket_Iterator<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &) const;
  // Check if two iterators point to the same position

protected:
  int forward_i (void);
  // Move forward by one element in the set.  Returns 0 when there's
  // no more item in the set after the current items, else 1.

  int reverse_i (void);
  // Move backward by one element in the set.  Returns 0 when there's
  // no more item in the set before the current item, else 1.

  ACE_Hash_Map_Manager_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> *map_man_;
  // Map we are iterating over.

  ssize_t index_;
  // Keeps track of how far we've advanced in the table.

  ACE_Hash_Map_Entry<EXT_ID, INT_ID> *next_;
  // Keeps track of how far we've advanced in a linked list in each
  // table slot.
};

template <class EXT_ID, class INT_ID, class HASH_KEY, class COMPARE_KEYS, class ACE_LOCK>
class ACE_Hash_Map_Reverse_Iterator_Ex : public ACE_Hash_Map_Iterator_Base_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK>
{
  // = TITLE
  //     Reverse iterator for the <ACE_Hash_Map_Manager_Ex>.
  //
  // = DESCRIPTION
  //     This class does not perform any internal locking of the
  //     <ACE_Hash_Map_Manager_Ex> it is iterating upon since locking is
  //     inherently inefficient and/or error-prone within an STL-style
  //     iterator.  If you require locking, you can explicitly use an
  //     <ACE_Guard> or <ACE_Read_Guard> on the <ACE_Hash_Map_Manager_Ex>'s
  //     internal lock, which is accessible via its <mutex> method.
public:
  // = Initialization method.
  ACE_Hash_Map_Reverse_Iterator_Ex (ACE_Hash_Map_Manager_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &mm,
                                    int head = 0);
  // = Iteration methods.
  int advance (void);
  // Move forward by one element in the set.  Returns 0 when all the
  // items in the set have been seen, else 1.

  void dump (void) const;
  // Dump the state of an object.

  // = STL styled iteration, compare, and reference functions.

  ACE_Hash_Map_Reverse_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &operator++ (void);
  // Prefix reverse.

  ACE_Hash_Map_Reverse_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> operator++ (int);
  // Postfix reverse.

  ACE_Hash_Map_Reverse_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> &operator-- (void);
  // Prefix advance.

  ACE_Hash_Map_Reverse_Iterator_Ex<EXT_ID, INT_ID, HASH_KEY, COMPARE_KEYS, ACE_LOCK> operator-- (int);
  // Postfix advance.

  ACE_ALLOC_HOOK_DECLARE;
  // Declare the dynamic allocation hooks.
};

template <class EXT_ID, class INT_ID, class ACE_LOCK>
class ACE_Hash_Map_Manager : public ACE_Hash_Map_Manager_Ex<EXT_ID, INT_ID, ACE_Hash<EXT_ID>, ACE_Equal_To<EXT_ID>, ACE_LOCK>
{
  // = TITLE
  //     Wrapper for backward compatibility.
  //
  // = DESCRIPTION
  //
  //     This implementation of a map uses a hash table.  This class
  //     expects that the <EXT_ID> contains a method called <hash>.
  //     In addition, the <EXT_ID> must support <operator==>.  Both of
  //     these constraints can be alleviated via template
  //     specialization, as shown in the $ACE_ROOT/tests/Conn_Test.cpp
  //     test.
  //
public:
  ACE_Hash_Map_Manager (ACE_Allocator *alloc = 0);
  // Initialize a <Hash_Map_Manager> with default size.

  ACE_Hash_Map_Manager (size_t size,
                        ACE_Allocator *alloc = 0);
  // Initialize a <Hash_Map_Manager> with size <length>.

  // = The following two are necessary for template specialization of
  // ACE_Hash_Map_Manager to work.
  int equal (const EXT_ID &id1, const EXT_ID &id2);
  u_long hash (const EXT_ID &ext_id);
};

template <class EXT_ID, class INT_ID, class ACE_LOCK>
class ACE_Hash_Map_Iterator : public ACE_Hash_Map_Iterator_Ex<EXT_ID, INT_ID, ACE_Hash<EXT_ID>, ACE_Equal_To<EXT_ID>, ACE_LOCK>
{
  // = TITLE
  //     Wrapper for backward compatibility.
  //
public:
  // = Initialization method.
  ACE_Hash_Map_Iterator (ACE_Hash_Map_Manager<EXT_ID, INT_ID, ACE_LOCK> &mm,
                         int tail = 0);
  // Construct from map

  ACE_Hash_Map_Iterator (const ACE_Hash_Map_Iterator_Ex<EXT_ID, INT_ID, ACE_Hash<EXT_ID>, ACE_Equal_To<EXT_ID>, ACE_LOCK> &base);
  // Construct from base

  ACE_Hash_Map_Iterator<EXT_ID, INT_ID, ACE_LOCK> &
  operator= (const ACE_Hash_Map_Iterator_Ex<EXT_ID, INT_ID, ACE_Hash<EXT_ID>, ACE_Equal_To<EXT_ID>, ACE_LOCK> &base);
  // Assignment from base
};

template <class EXT_ID, class INT_ID, class ACE_LOCK>
class ACE_Hash_Map_Reverse_Iterator : public ACE_Hash_Map_Reverse_Iterator_Ex<EXT_ID, INT_ID, ACE_Hash<EXT_ID>, ACE_Equal_To<EXT_ID>, ACE_LOCK>
{
  // = TITLE
  //     Wrapper for backward compatibility.
  //
public:
  // = Initialization method.
  ACE_Hash_Map_Reverse_Iterator (ACE_Hash_Map_Manager<EXT_ID, INT_ID, ACE_LOCK> &mm,
                                 int head = 0);

  ACE_Hash_Map_Reverse_Iterator (const ACE_Hash_Map_Reverse_Iterator_Ex<EXT_ID, INT_ID, ACE_Hash<EXT_ID>, ACE_Equal_To<EXT_ID>, ACE_LOCK> &base);
  // Construct from base

  ACE_Hash_Map_Reverse_Iterator<EXT_ID, INT_ID, ACE_LOCK> &
  operator= (const ACE_Hash_Map_Reverse_Iterator_Ex<EXT_ID, INT_ID, ACE_Hash<EXT_ID>, ACE_Equal_To<EXT_ID>, ACE_LOCK> &base);
  // Assignment from base
};

#if defined (__ACE_INLINE__)
// Include ace/Hash_Map_Manager_T.i on all platforms excluding SunCC.
// This nonsense is necessary since SunCC (version 4.2) cannot inline
// the code in ace/Hash_Map_Manager_T.i (with the fast option).
# if !defined (__SUNPRO_CC)
#  include "ace/Hash_Map_Manager_T.i"
# endif /* ! __SUNPRO_CC */
#endif /* __ACE_INLINE__ */

#if defined (ACE_TEMPLATES_REQUIRE_SOURCE)
#include "ace/Hash_Map_Manager_T.cpp"
#endif /* ACE_TEMPLATES_REQUIRE_SOURCE */

#if defined (ACE_TEMPLATES_REQUIRE_PRAGMA)
#pragma implementation ("Hash_Map_Manager_T.cpp")
#endif /* ACE_TEMPLATES_REQUIRE_PRAGMA */

#endif /* ACE_HASH_MAP_MANAGER_T_H */