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/* -*- C++ -*- */
//=============================================================================
/**
* @file Unbounded_Queue.h
*
* $Id$
*
* @author Doug Schmidt
*/
//=============================================================================
#ifndef ACE_UNBOUNDED_QUEUE_H
#define ACE_UNBOUNDED_QUEUE_H
#include "ace/pre.h"
#include "ace/Node.h"
#if !defined (ACE_LACKS_PRAGMA_ONCE)
# pragma once
#endif /* ACE_LACKS_PRAGMA_ONCE */
// For size_t under Chorus
#include "ace/OS_Memory.h"
class ACE_Allocator;
template <class T>
class ACE_Unbounded_Queue;
/**
* @class ACE_Unbounded_Queue_Iterator
*
* @brief Implement an iterator over an unbounded queue.
*/
template <class T>
class ACE_Unbounded_Queue_Iterator
{
public:
// = Initialization method.
ACE_Unbounded_Queue_Iterator (ACE_Unbounded_Queue<T> &q, int end = 0);
// = Iteration methods.
/// Pass back the <next_item> that hasn't been seen in the queue.
/// Returns 0 when all items have been seen, else 1.
int next (T *&next_item);
/// Move forward by one element in the set. Returns 0 when all the
/// items in the queue have been seen, else 1.
int advance (void);
/// Move to the first element in the queue. Returns 0 if the
/// queue is empty, else 1.
int first (void);
/// Returns 1 when all items have been seen, else 0.
int done (void) const;
/// Dump the state of an object.
void dump (void) const;
/// Declare the dynamic allocation hooks.
ACE_ALLOC_HOOK_DECLARE;
private:
/// Pointer to the current node in the iteration.
ACE_Node<T> *current_;
/// Pointer to the queue we're iterating over.
ACE_Unbounded_Queue<T> &queue_;
};
/**
* @class ACE_Unbounded_Queue_Const_Iterator
*
* @brief Implement an iterator over an const unbounded queue.
*/
template <class T>
class ACE_Unbounded_Queue_Const_Iterator
{
public:
// = Initialization method.
ACE_Unbounded_Queue_Const_Iterator (const ACE_Unbounded_Queue<T> &q, int end = 0);
// = Iteration methods.
/// Pass back the <next_item> that hasn't been seen in the queue.
/// Returns 0 when all items have been seen, else 1.
int next (T *&next_item);
/// Move forward by one element in the set. Returns 0 when all the
/// items in the queue have been seen, else 1.
int advance (void);
/// Move to the first element in the queue. Returns 0 if the
/// queue is empty, else 1.
int first (void);
/// Returns 1 when all items have been seen, else 0.
int done (void) const;
/// Dump the state of an object.
void dump (void) const;
/// Declare the dynamic allocation hooks.
ACE_ALLOC_HOOK_DECLARE;
private:
/// Pointer to the current node in the iteration.
ACE_Node<T> *current_;
/// Pointer to the queue we're iterating over.
const ACE_Unbounded_Queue<T> &queue_;
};
/**
* @class ACE_Unbounded_Queue
*
* @brief A Queue of "infinite" length.
*
* This implementation of an unbounded queue uses a circular
* linked list with a dummy node.
*
* <b> Requirements and Performance Characteristics</b>
* - Internal Structure
* Circular linked list
* - Duplicates allowed?
* Yes
* - Random access allowed?
* No
* - Search speed
* N/A
* - Insert/replace speed
* N/A
* - Iterator still valid after change to container?
* Yes
* - Frees memory for removed elements?
* Yes
* - Items inserted by
* Value
* - Requirements for contained type
* -# Default constructor
* -# Copy constructor
* -# operator=
*
*/
template <class T>
class ACE_Unbounded_Queue
{
public:
friend class ACE_Unbounded_Queue_Iterator<T>;
friend class ACE_Unbounded_Queue_Const_Iterator<T>;
// Trait definition.
typedef ACE_Unbounded_Queue_Iterator<T> ITERATOR;
typedef ACE_Unbounded_Queue_Const_Iterator<T> CONST_ITERATOR;
// = Initialization and termination methods.
/// construction. Use user specified allocation strategy
/// if specified.
/**
* Initialize an empty queue using the strategy provided.
*/
ACE_Unbounded_Queue (ACE_Allocator *alloc = 0);
/// Copy constructor.
/**
* Initialize the queue to be a copy of the provided queue.
*/
ACE_Unbounded_Queue (const ACE_Unbounded_Queue<T> &);
/// Assignment operator.
/**
* Perform a deep copy of rhs.
*/
void operator= (const ACE_Unbounded_Queue<T> &);
/// Destructor.
/**
* Clean up the memory for the queue.
*/
~ACE_Unbounded_Queue (void);
// = Check boundary conditions.
/// Returns 1 if the container is empty, otherwise returns 0.
/**
* Constant time check to see if the queue is empty.
*/
int is_empty (void) const;
/// Returns 0.
/**
* The queue cannot be full, so it always returns 0.
*/
int is_full (void) const;
// = Classic queue operations.
/// Adds <new_item> to the tail of the queue. Returns 0 on success,
/// -1 on failure.
/**
* Insert an item at the end of the queue.
*/
int enqueue_tail (const T &new_item);
/// Adds <new_item> to the head of the queue. Returns 0 on success,
/// -1 on failure.
/**
* Insert an item at the head of the queue.
*/
int enqueue_head (const T &new_item);
/// Removes and returns the first <item> on the queue. Returns 0 on
/// success, -1 if the queue was empty.
/**
* Remove an item from the head of the queue.
*/
int dequeue_head (T &item);
// = Additional utility methods.
/// Reset the <ACE_Unbounded_Queue> to be empty and release all its
/// dynamically allocated resources.
/**
* Delete the queue nodes.
*/
void reset (void);
/// Get the <slot>th element in the set. Returns -1 if the element
/// isn't in the range {0..<size> - 1}, else 0.
/**
* Find the item in the queue between 0 and the provided index of the
* queue.
*/
int get (T *&item, size_t slot = 0) const;
///Set the <slot>th element of the queue to <item>.
/**
* Set the <slot>th element in the set. Will pad out the set with
* empty nodes if <slot> is beyond the range {0..<size> - 1}.
* Returns -1 on failure, 0 if <slot> isn't initially in range, and
* 0 otherwise.
*/
int set (const T &item, size_t slot);
/// The number of items in the queue.
/**
* Return the size of the queue.
*/
size_t size (void) const;
/// Dump the state of an object.
void dump (void) const;
// = STL-styled unidirectional iterator factory.
ACE_Unbounded_Queue_Iterator<T> begin (void);
ACE_Unbounded_Queue_Iterator<T> end (void);
/// Declare the dynamic allocation hooks.
ACE_ALLOC_HOOK_DECLARE;
protected:
/// Delete all the nodes in the queue.
void delete_nodes (void);
/// Copy nodes into this queue.
void copy_nodes (const ACE_Unbounded_Queue<T> &);
/// Pointer to the dummy node in the circular linked Queue.
ACE_Node<T> *head_;
/// Current size of the queue.
size_t cur_size_;
/// Allocation Strategy of the queue.
ACE_Allocator *allocator_;
};
#if defined (__ACE_INLINE__)
#include "ace/Unbounded_Queue.inl"
#endif /* __ACE_INLINE__ */
#if defined (ACE_TEMPLATES_REQUIRE_SOURCE)
#include "ace/Unbounded_Queue.cpp"
#endif /* ACE_TEMPLATES_REQUIRE_SOURCE */
#if defined (ACE_TEMPLATES_REQUIRE_PRAGMA)
#pragma implementation ("Unbounded_Queue.cpp")
#endif /* ACE_TEMPLATES_REQUIRE_PRAGMA */
#include "ace/post.h"
#endif /* ACE_UNBOUNDED_QUEUE_H */
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