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/* -*- C++ -*- */
// $Id$
// ============================================================================
//
// = LIBRARY
// ace
//
// = FILENAME
// Managed_Object.h
//
// = AUTHORS
// David L. Levine
//
// ============================================================================
#ifndef ACE_MANAGED_OBJECT_H
#define ACE_MANAGED_OBJECT_H
#include "ace/pre.h"
#include "ace/OS.h"
#if !defined (ACE_LACKS_PRAGMA_ONCE)
# pragma once
#endif /* ACE_LACKS_PRAGMA_ONCE */
#include "ace/Object_Manager.h"
template <class TYPE>
class ACE_Cleanup_Adapter : public ACE_Cleanup
{
// = TITLE
// Adapter for ACE_Cleanup objects that allows them to be readily
// managed by the ACE_Object_Manager.
//
// = DESCRIPTION
// This template class adapts an object of any type to be an
// ACE_Cleanup object. The object can then be destroyed
// type-safely by the ACE_Object_Manager. This class is
// typically used to replace a cast; but, it's a bit cleaner and
// allows insertion of, say, run-time type identification
// internally if desired.
public:
ACE_Cleanup_Adapter (void);
// Default constructor.
virtual ~ACE_Cleanup_Adapter (void);
// Virtual destructor, needed by some compilers for vtable placement.
TYPE &object (void);
// Accessor for contained object.
private:
TYPE object_;
// Contained object.
};
template <class TYPE>
class ACE_Managed_Object
{
// = TITLE
// Wrapper for interface to allocate an object managed by the
// ACE_Object_Manager.
//
// = DESCRIPTION
// This template class wraps an interface that is used to
// allocate and access an object that is managed by the
// ACE_Object_Manager. Because static template member functions
// are not supported by some compilers, it is a separate
// (template) class.
//
// This interface is typically used to replace a static object
// with one that is dynamically allocated. It helps to avoid
// problems with order of static object
// construction/destruction. Managed objects won't be allocated
// until needed, but should be allocated when first needed. And
// they are destroyed in the reverse order of construction.
//
// <get_preallocated_object> accesses a "preallocated" object,
// i.e., one that is identified by a value in the
// ACE_Object_Manager:: Preallocated_Object enum. These objects
// are used internally by the ACE library.
//
// Hooks are provided for the application to preallocate objects
// via the same mechanism.
// ACE_APPLICATION_PREALLOCATED_OBJECT_DECLARATIONS can be used
// to define enum values;
// ACE_APPLICATION_PREALLOCATED_OBJECT_DEFINITIONS can be used
// to define the corresponding objects. The format of the ACE
// internal library definitions should be followed. And
// similarly, ACE_APPLICATION_PREALLOCATED_ARRAY_DECLARATIONS
// and ACE_APPLICATION_PREALLOCATED_ARRAY_DEFINITIONS can be
// used to preallocate arrays.
//
// By default, preallocation uses dynamic allocation. The
// preallocated objects and arrays are allocated off the heap in
// the ACE_Object_Manager constructor. To statically place the
// preallocated objects in program global data instead of on the
// heap, #define ACE_HAS_STATIC_PREALLOCATION prior to building
// the ACE library.
public:
static TYPE *get_preallocated_object (ACE_Object_Manager::Preallocated_Object id)
{
// The preallocated objects are in a separate, "read-only" array so
// that this function doesn't need a lock. Also, because it is
// intended _only_ for use with hard-code values, it performs no
// range checking on "id".
// Cast the return type of the the object pointer based
// on the type of the function template parameter.
return &((ACE_Cleanup_Adapter<TYPE> *)
ACE_Object_Manager::preallocated_object[id])->object ();
}
// Get the preallocated object identified by "id". Returns a
// pointer to the object. Beware: no error indication is provided,
// because it can _only_ be used for accessing preallocated objects.
// Note: the function definition is inlined here so that it compiles
// on AIX 4.1 w/xlC v. 3.01.
static TYPE *get_preallocated_array (ACE_Object_Manager::Preallocated_Array id)
{
// The preallocated array are in a separate, "read-only" array so
// that this function doesn't need a lock. Also, because it is
// intended _only_ for use with hard-code values, it performs no
// range checking on "id".
// Cast the return type of the the object pointer based
// on the type of the function template parameter.
return &((ACE_Cleanup_Adapter<TYPE> *)
ACE_Object_Manager::preallocated_array[id])->object ();
}
// Get the preallocated array identified by "id". Returns a
// pointer to the array. Beware: no error indication is provided,
// because it can _only_ be used for accessing preallocated arrays.
// Note: the function definition is inlined here so that it compiles
// on AIX 4.1 w/xlC v. 3.01.
private:
// Disallow instantiation of this class.
ACE_UNIMPLEMENTED_FUNC (ACE_Managed_Object (void))
ACE_UNIMPLEMENTED_FUNC (ACE_Managed_Object (const ACE_Managed_Object<TYPE> &))
ACE_UNIMPLEMENTED_FUNC (void operator= (const ACE_Managed_Object<TYPE> &))
friend class this_prevents_compiler_warning_about_only_private_constructors;
};
#if defined (__ACE_INLINE__)
#include "ace/Managed_Object.i"
#endif /* __ACE_INLINE__ */
#if defined (ACE_TEMPLATES_REQUIRE_SOURCE)
#include "ace/Managed_Object.cpp"
#endif /* ACE_TEMPLATES_REQUIRE_SOURCE */
#if defined (ACE_TEMPLATES_REQUIRE_PRAGMA)
#pragma implementation ("Managed_Object.cpp")
#endif /* ACE_TEMPLATES_REQUIRE_PRAGMA */
#include "ace/post.h"
#endif /* ACE_MANAGED_OBJECT_H */
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