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/**
* @file llsingleton.cpp
* @author Brad Kittenbrink
*
* $LicenseInfo:firstyear=2009&license=viewerlgpl$
* Second Life Viewer Source Code
* Copyright (C) 2010, Linden Research, Inc.
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation;
* version 2.1 of the License only.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*
* Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA
* $/LicenseInfo$
*/
#include "linden_common.h"
#include "llsingleton.h"
#include "llerror.h"
#include "llerrorcontrol.h" // LLError::is_available()
#include "lldependencies.h"
#include "llcoro_get_id.h"
#include <boost/foreach.hpp>
#include <boost/unordered_map.hpp>
#include <algorithm>
#include <iostream> // std::cerr in dire emergency
#include <sstream>
#include <stdexcept>
namespace {
void log(LLError::ELevel level,
const char* p1, const char* p2, const char* p3, const char* p4);
void logdebugs(const char* p1="", const char* p2="", const char* p3="", const char* p4="");
bool oktolog();
} // anonymous namespace
// Our master list of all LLSingletons is itself an LLSingleton. We used to
// store it in a function-local static, but that could get destroyed before
// the last of the LLSingletons -- and ~LLSingletonBase() definitely wants to
// remove itself from the master list. Since the whole point of this master
// list is to help track inter-LLSingleton dependencies, and since we have
// this implicit dependency from every LLSingleton to the master list, make it
// an LLSingleton.
class LLSingletonBase::MasterList:
public LLSingleton<LLSingletonBase::MasterList>
{
LLSINGLETON_EMPTY_CTOR(MasterList);
public:
// No need to make this private with accessors; nobody outside this source
// file can see it.
// This is the master list of all instantiated LLSingletons (save the
// MasterList itself) in arbitrary order. You MUST call dep_sort() before
// traversing this list.
LLSingletonBase::list_t mMaster;
// We need to maintain a stack of LLSingletons currently being
// initialized, either in the constructor or in initSingleton(). However,
// managing that as a stack depends on having a DISTINCT 'initializing'
// stack for every C++ stack in the process! And we have a distinct C++
// stack for every running coroutine. It would be interesting and cool to
// implement a generic coroutine-local-storage mechanism and use that
// here. The trouble is that LLCoros is itself an LLSingleton, so
// depending on LLCoros functionality could dig us into infinite
// recursion. (Moreover, when we reimplement LLCoros on top of
// Boost.Fiber, that library already provides fiber_specific_ptr -- so
// it's not worth a great deal of time and energy implementing a generic
// equivalent on top of boost::dcoroutine, which is on its way out.)
// Instead, use a map of llcoro::id to select the appropriate
// coro-specific 'initializing' stack. llcoro::get_id() is carefully
// implemented to avoid requiring LLCoros.
typedef boost::unordered_map<llcoro::id, LLSingletonBase::list_t> InitializingMap;
InitializingMap mInitializing;
// non-static method, cf. LLSingletonBase::get_initializing()
list_t& get_initializing_()
{
// map::operator[] has find-or-create semantics, exactly what we need
// here. It returns a reference to the selected mapped_type instance.
return mInitializing[llcoro::get_id()];
}
void cleanup_initializing_()
{
InitializingMap::iterator found = mInitializing.find(llcoro::get_id());
if (found != mInitializing.end())
{
mInitializing.erase(found);
}
}
};
//static
LLSingletonBase::list_t& LLSingletonBase::get_master()
{
return LLSingletonBase::MasterList::instance().mMaster;
}
void LLSingletonBase::add_master()
{
// As each new LLSingleton is constructed, add to the master list.
get_master().push_back(this);
}
void LLSingletonBase::remove_master()
{
// When an LLSingleton is destroyed, remove from master list.
// add_master() used to capture the iterator to the newly-added list item
// so we could directly erase() it from the master list. Unfortunately
// that runs afoul of destruction-dependency order problems. So search the
// master list, and remove this item IF FOUND. We have few enough
// LLSingletons, and they are so rarely destroyed (once per run), that the
// cost of a linear search should not be an issue.
get_master().remove(this);
}
//static
LLSingletonBase::list_t& LLSingletonBase::get_initializing()
{
return LLSingletonBase::MasterList::instance().get_initializing_();
}
//static
LLSingletonBase::list_t& LLSingletonBase::get_initializing_from(MasterList* master)
{
return master->get_initializing_();
}
LLSingletonBase::~LLSingletonBase() {}
void LLSingletonBase::push_initializing(const char* name)
{
// log BEFORE pushing so logging singletons don't cry circularity
log_initializing("Pushing", name);
get_initializing().push_back(this);
}
void LLSingletonBase::pop_initializing()
{
list_t& list(get_initializing());
if (list.empty())
{
logerrs("Underflow in stack of currently-initializing LLSingletons at ",
demangle(typeid(*this).name()).c_str(), "::getInstance()");
}
// Now we know list.back() exists: capture it
LLSingletonBase* back(list.back());
// and pop it
list.pop_back();
// The viewer launches an open-ended number of coroutines. While we don't
// expect most of them to initialize LLSingleton instances, our present
// get_initializing() logic could lead to an open-ended number of map
// entries. So every time we pop the stack back to empty, delete the entry
// entirely.
if (list.empty())
{
MasterList::instance().cleanup_initializing_();
}
// Now validate the newly-popped LLSingleton.
if (back != this)
{
logerrs("Push/pop mismatch in stack of currently-initializing LLSingletons: ",
demangle(typeid(*this).name()).c_str(), "::getInstance() trying to pop ",
demangle(typeid(*back).name()).c_str());
}
// log AFTER popping so logging singletons don't cry circularity
log_initializing("Popping", typeid(*back).name());
}
//static
void LLSingletonBase::log_initializing(const char* verb, const char* name)
{
if (oktolog())
{
LL_DEBUGS("LLSingleton") << verb << ' ' << demangle(name) << ';';
list_t& list(get_initializing());
for (list_t::const_reverse_iterator ri(list.rbegin()), rend(list.rend());
ri != rend; ++ri)
{
LLSingletonBase* sb(*ri);
LL_CONT << ' ' << demangle(typeid(*sb).name());
}
LL_ENDL;
}
}
void LLSingletonBase::capture_dependency(list_t& initializing, EInitState initState)
{
// Did this getInstance() call come from another LLSingleton, or from
// vanilla application code? Note that although this is a nontrivial
// method, the vast majority of its calls arrive here with initializing
// empty().
if (! initializing.empty())
{
// getInstance() is being called by some other LLSingleton. But -- is
// this a circularity? That is, does 'this' already appear in the
// initializing stack?
// For what it's worth, normally 'initializing' should contain very
// few elements.
list_t::const_iterator found =
std::find(initializing.begin(), initializing.end(), this);
if (found != initializing.end())
{
// Report the circularity. Requiring the coder to dig through the
// logic to diagnose exactly how we got here is less than helpful.
std::ostringstream out;
for ( ; found != initializing.end(); ++found)
{
// 'found' is an iterator; *found is an LLSingletonBase*; **found
// is the actual LLSingletonBase instance.
LLSingletonBase* foundp(*found);
out << demangle(typeid(*foundp).name()) << " -> ";
}
// We promise to capture dependencies from both the constructor
// and the initSingleton() method, so an LLSingleton's instance
// pointer is on the initializing list during both. Now that we've
// detected circularity, though, we must distinguish the two. If
// the recursive call is from the constructor, we CAN'T honor it:
// otherwise we'd be returning a pointer to a partially-
// constructed object! But from initSingleton() is okay: that
// method exists specifically to support circularity.
// Decide which log helper to call based on initState. They have
// identical signatures.
((initState == CONSTRUCTING)? logerrs : logwarns)
("LLSingleton circularity: ", out.str().c_str(),
demangle(typeid(*this).name()).c_str(), "");
}
else
{
// Here 'this' is NOT already in the 'initializing' stack. Great!
// Record the dependency.
// initializing.back() is the LLSingletonBase* currently being
// initialized. Store 'this' in its mDepends set.
LLSingletonBase* current(initializing.back());
if (current->mDepends.insert(this).second)
{
// only log the FIRST time we hit this dependency!
logdebugs(demangle(typeid(*current).name()).c_str(),
" depends on ", demangle(typeid(*this).name()).c_str());
}
}
}
}
//static
LLSingletonBase::vec_t LLSingletonBase::dep_sort()
{
// While it would theoretically be possible to maintain a static
// SingletonDeps through the life of the program, dynamically adding and
// removing LLSingletons as they are created and destroyed, in practice
// it's less messy to construct it on demand. The overhead of doing so
// should happen basically twice: once for cleanupAll(), once for
// deleteAll().
typedef LLDependencies<LLSingletonBase*> SingletonDeps;
SingletonDeps sdeps;
list_t& master(get_master());
BOOST_FOREACH(LLSingletonBase* sp, master)
{
// Build the SingletonDeps structure by adding, for each
// LLSingletonBase* sp in the master list, sp itself. It has no
// associated value type in our SingletonDeps, hence the 0. We don't
// record the LLSingletons it must follow; rather, we record the ones
// it must precede. Copy its mDepends to a KeyList to express that.
sdeps.add(sp, 0,
SingletonDeps::KeyList(),
SingletonDeps::KeyList(sp->mDepends.begin(), sp->mDepends.end()));
}
vec_t ret;
ret.reserve(master.size());
// We should be able to effect this with a transform_iterator that
// extracts just the first (key) element from each sorted_iterator, then
// uses vec_t's range constructor... but frankly this is more
// straightforward, as long as we remember the above reserve() call!
BOOST_FOREACH(SingletonDeps::sorted_iterator::value_type pair, sdeps.sort())
{
ret.push_back(pair.first);
}
// The master list is not itself pushed onto the master list. Add it as
// the very last entry -- it is the LLSingleton on which ALL others
// depend! -- so our caller will process it.
ret.push_back(MasterList::getInstance());
return ret;
}
//static
void LLSingletonBase::cleanupAll()
{
// It's essential to traverse these in dependency order.
BOOST_FOREACH(LLSingletonBase* sp, dep_sort())
{
// Call cleanupSingleton() only if we haven't already done so for this
// instance.
if (! sp->mCleaned)
{
sp->mCleaned = true;
logdebugs("calling ",
demangle(typeid(*sp).name()).c_str(), "::cleanupSingleton()");
try
{
sp->cleanupSingleton();
}
catch (const std::exception& e)
{
logwarns("Exception in ", demangle(typeid(*sp).name()).c_str(),
"::cleanupSingleton(): ", e.what());
}
catch (...)
{
logwarns("Unknown exception in ", demangle(typeid(*sp).name()).c_str(),
"::cleanupSingleton()");
}
}
}
}
//static
void LLSingletonBase::deleteAll()
{
// It's essential to traverse these in dependency order.
BOOST_FOREACH(LLSingletonBase* sp, dep_sort())
{
// Capture the class name first: in case of exception, don't count on
// being able to extract it later.
const std::string name = demangle(typeid(*sp).name());
try
{
// Call static method through instance function pointer.
if (! sp->mDeleteSingleton)
{
// This Should Not Happen... but carry on.
logwarns(name.c_str(), "::mDeleteSingleton not initialized!");
}
else
{
// properly initialized: call it.
logdebugs("calling ", name.c_str(), "::deleteSingleton()");
// From this point on, DO NOT DEREFERENCE sp!
sp->mDeleteSingleton();
}
}
catch (const std::exception& e)
{
logwarns("Exception in ", name.c_str(), "::deleteSingleton(): ", e.what());
}
catch (...)
{
logwarns("Unknown exception in ", name.c_str(), "::deleteSingleton()");
}
}
}
/*------------------------ Final cleanup management ------------------------*/
class LLSingletonBase::MasterRefcount
{
public:
// store a POD int so it will be statically initialized to 0
int refcount;
};
static LLSingletonBase::MasterRefcount sMasterRefcount;
LLSingletonBase::ref_ptr_t LLSingletonBase::get_master_refcount()
{
// Calling this method constructs a new ref_ptr_t, which implicitly calls
// intrusive_ptr_add_ref(MasterRefcount*).
return &sMasterRefcount;
}
void intrusive_ptr_add_ref(LLSingletonBase::MasterRefcount* mrc)
{
// Count outstanding SingletonLifetimeManager instances.
++mrc->refcount;
}
void intrusive_ptr_release(LLSingletonBase::MasterRefcount* mrc)
{
// Notice when each SingletonLifetimeManager instance is destroyed.
if (! --mrc->refcount)
{
// The last instance was destroyed. Time to kill any remaining
// LLSingletons -- but in dependency order.
LLSingletonBase::deleteAll();
}
}
/*---------------------------- Logging helpers -----------------------------*/
namespace {
bool oktolog()
{
// See comments in log() below.
return sMasterRefcount.refcount && LLError::is_available();
}
void log(LLError::ELevel level,
const char* p1, const char* p2, const char* p3, const char* p4)
{
// Check whether we're in the implicit final LLSingletonBase::deleteAll()
// call. We've carefully arranged for deleteAll() to be called when the
// last SingletonLifetimeManager instance is destroyed -- in other words,
// when the last translation unit containing an LLSingleton instance
// cleans up static data. That could happen after std::cerr is destroyed!
// The is_available() test below ensures that we'll stop logging once
// LLError has been cleaned up. If we had a similar portable test for
// std::cerr, this would be a good place to use it. As we do not, just
// don't log anything during implicit final deleteAll(). Detect that by
// the master refcount having gone to zero.
if (sMasterRefcount.refcount == 0)
return;
// Check LLError::is_available() because some of LLError's infrastructure
// is itself an LLSingleton. If that LLSingleton has not yet been
// initialized, trying to log will engage LLSingleton machinery... and
// around and around we go.
if (LLError::is_available())
{
LL_VLOGS(level, "LLSingleton") << p1 << p2 << p3 << p4 << LL_ENDL;
}
else
{
// Caller may be a test program, or something else whose stderr is
// visible to the user.
std::cerr << p1 << p2 << p3 << p4 << std::endl;
}
}
void logdebugs(const char* p1, const char* p2, const char* p3, const char* p4)
{
log(LLError::LEVEL_DEBUG, p1, p2, p3, p4);
}
} // anonymous namespace
//static
void LLSingletonBase::logwarns(const char* p1, const char* p2, const char* p3, const char* p4)
{
log(LLError::LEVEL_WARN, p1, p2, p3, p4);
}
//static
void LLSingletonBase::logerrs(const char* p1, const char* p2, const char* p3, const char* p4)
{
log(LLError::LEVEL_ERROR, p1, p2, p3, p4);
// The other important side effect of LL_ERRS() is
// https://www.youtube.com/watch?v=OMG7paGJqhQ (emphasis on OMG)
LLError::crashAndLoop(std::string());
}
std::string LLSingletonBase::demangle(const char* mangled)
{
return LLError::Log::demangle(mangled);
}
|