David Robillard
640a358fdc
git-svn-id: svn://localhost/ardour2/branches/3.0@5997 d708f5d6-7413-0410-9779-e7cbd77b26cf
256 lines
8.3 KiB
C++
256 lines
8.3 KiB
C++
/*
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Copyright (C) 2000-2007 Paul Davis
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This program is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 2 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, write to the Free Software
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Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
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*/
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#ifndef __pbd_rcu_h__
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#define __pbd_rcu_h__
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#include "boost/shared_ptr.hpp"
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#include "glibmm/thread.h"
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#include <list>
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/** @file Defines a set of classes to implement Read-Copy-Update. We do not attempt to define RCU here - use google.
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The design consists of two parts: an RCUManager and an RCUWriter.
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*/
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/** An RCUManager is an object which takes over management of a pointer to another object.
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It provides three key methods:
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- reader() : obtains a shared pointer to the managed object that may be used for reading, without synchronization
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- write_copy() : obtains a shared pointer to the object that may be used for writing/modification
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- update() : accepts a shared pointer to a (presumed) modified instance of the object and causes all
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future reader() and write_copy() calls to use that instance.
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Any existing users of the value returned by reader() can continue to use their copy even as a write_copy()/update() takes place.
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The RCU manager will manage the various instances of "the managed object" in a way that is transparent to users of the manager
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and managed object.
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*/
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template<class T>
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class RCUManager
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{
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public:
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RCUManager (T* new_rcu_value) {
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x.m_rcu_value = new boost::shared_ptr<T> (new_rcu_value);
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}
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virtual ~RCUManager() { delete x.m_rcu_value; }
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boost::shared_ptr<T> reader () const { return *((boost::shared_ptr<T> *) g_atomic_pointer_get (&x.gptr)); }
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/* this is an abstract base class - how these are implemented depends on the assumptions
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that one can make about the users of the RCUManager. See SerializedRCUManager below
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for one implementation.
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*/
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virtual boost::shared_ptr<T> write_copy () = 0;
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virtual bool update (boost::shared_ptr<T> new_value) = 0;
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protected:
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/* ordinarily this would simply be a declaration of a ptr to a shared_ptr<T>. however, the atomic
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operations that we are using (from glib) have sufficiently strict typing that it proved hard
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to get them to accept even a cast value of the ptr-to-shared-ptr() as the argument to get()
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and comp_and_exchange(). Consequently, we play a litle trick here that relies on the fact
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that sizeof(A*) == sizeof(B*) no matter what the types of A and B are. for most purposes
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we will use x.m_rcu_value, but when we need to use an atomic op, we use x.gptr. Both expressions
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evaluate to the same address.
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*/
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union {
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boost::shared_ptr<T>* m_rcu_value;
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mutable volatile gpointer gptr;
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} x;
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};
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/** Serialized RCUManager implements the RCUManager interface. It is based on the
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following key assumption: among its users we have readers that are bound by
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RT time constraints, and writers who are not. Therefore, we do not care how
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slow the write_copy()/update() operations are, or what synchronization
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primitives they use.
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Because of this design assumption, this class will serialize all
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writers. That is, objects calling write_copy()/update() will be serialized by
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a mutex. Only a single writer may be in the middle of write_copy()/update();
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all other writers will block until the first has finished. The order of
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execution of multiple writers if more than one is blocked in this way is
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undefined.
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The class maintains a lock-protected "dead wood" list of old value of
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*m_rcu_value (i.e. shared_ptr<T>). The list is cleaned up every time we call
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write_copy(). If the list is the last instance of a shared_ptr<T> that
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references the object (determined by shared_ptr::unique()) then we
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erase it from the list, thus deleting the object it points to. This is lazy
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destruction - the SerializedRCUManager assumes that there will sufficient
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calls to write_copy() to ensure that we do not inadvertently leave objects
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around for excessive periods of time.
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For extremely well defined circumstances (i.e. it is known that there are no
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other writer objects in existence), SerializedRCUManager also provides a
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flush() method that will unconditionally clear out the "dead wood" list. It
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must be used with significant caution, although the use of shared_ptr<T>
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means that no actual objects will be deleted incorrectly if this is misused.
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*/
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template<class T>
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class SerializedRCUManager : public RCUManager<T>
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{
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public:
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SerializedRCUManager(T* new_rcu_value)
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: RCUManager<T>(new_rcu_value)
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{
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}
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boost::shared_ptr<T> write_copy ()
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{
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m_lock.lock();
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// clean out any dead wood
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typename std::list<boost::shared_ptr<T> >::iterator i;
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for (i = m_dead_wood.begin(); i != m_dead_wood.end(); ) {
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if ((*i).unique()) {
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i = m_dead_wood.erase (i);
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} else {
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++i;
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}
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}
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/* store the current so that we can do compare and exchange
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when someone calls update(). Notice that we hold
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a lock, so this store of m_rcu_value is atomic.
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*/
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current_write_old = RCUManager<T>::x.m_rcu_value;
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boost::shared_ptr<T> new_copy (new T(**current_write_old));
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return new_copy;
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/* notice that the write lock is still held: update() MUST
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be called or we will cause another writer to stall.
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*/
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}
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bool update (boost::shared_ptr<T> new_value)
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{
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/* we still hold the write lock - other writers are locked out */
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boost::shared_ptr<T>* new_spp = new boost::shared_ptr<T> (new_value);
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/* update, by atomic compare&swap. Only succeeds if the old
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value has not been changed.
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XXX but how could it? we hold the freakin' lock!
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*/
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bool ret = g_atomic_pointer_compare_and_exchange (&RCUManager<T>::x.gptr,
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(gpointer) current_write_old,
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(gpointer) new_spp);
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if (ret) {
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// successful update : put the old value into dead_wood,
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m_dead_wood.push_back (*current_write_old);
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// now delete it - this gets rid of the shared_ptr<T> but
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// because dead_wood contains another shared_ptr<T> that
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// references the same T, the underlying object lives on
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delete current_write_old;
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}
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/* unlock, allowing other writers to proceed */
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m_lock.unlock();
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return ret;
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}
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void flush () {
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Glib::Mutex::Lock lm (m_lock);
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m_dead_wood.clear ();
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}
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private:
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Glib::Mutex m_lock;
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boost::shared_ptr<T>* current_write_old;
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std::list<boost::shared_ptr<T> > m_dead_wood;
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};
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/** RCUWriter is a convenience object that implements write_copy/update via
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lifetime management. Creating the object obtains a writable copy, which can
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be obtained via the get_copy() method; deleting the object will update
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the manager's copy. Code doing a write/update thus looks like:
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{
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RCUWriter writer (object_manager);
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boost::shared_ptr<T> copy = writer.get_copy();
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... modify copy ...
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} <= writer goes out of scope, update invoked
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*/
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template<class T>
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class RCUWriter
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{
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public:
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RCUWriter(RCUManager<T>& manager)
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: m_manager(manager) {
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m_copy = m_manager.write_copy();
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}
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~RCUWriter() {
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if (m_copy.unique()) {
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/* As intended, our copy is the only reference
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to the object pointed to by m_copy. Update
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the manager with the (presumed) modified
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version.
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*/
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m_manager.update(m_copy);
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} else {
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/* This means that some other object is using our copy
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of the object. This can only happen if the scope in
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which this RCUWriter exists passed it to a function
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that created a persistent reference to it, since the
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copy was private to this particular RCUWriter. Doing
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so will not actually break anything but it violates
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the design intention here and so we do not bother to
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update the manager's copy.
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XXX should we print a warning about this?
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*/
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}
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}
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boost::shared_ptr<T> get_copy() const { return m_copy; }
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private:
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RCUManager<T>& m_manager;
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boost::shared_ptr<T> m_copy;
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};
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#endif /* __pbd_rcu_h__ */
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