/**************************************************************
 * 
 * Licensed to the Apache Software Foundation (ASF) under one
 * or more contributor license agreements.  See the NOTICE file
 * distributed with this work for additional information
 * regarding copyright ownership.  The ASF licenses this file
 * to you under the Apache License, Version 2.0 (the
 * "License"); you may not use this file except in compliance
 * with the License.  You may obtain a copy of the License at
 * 
 *   http://www.apache.org/licenses/LICENSE-2.0
 * 
 * Unless required by applicable law or agreed to in writing,
 * software distributed under the License is distributed on an
 * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
 * KIND, either express or implied.  See the License for the
 * specific language governing permissions and limitations
 * under the License.
 * 
 *************************************************************/



// MARKER(update_precomp.py): autogen include statement, do not remove
#include "precompiled_cppu.hxx"
#include <hash_set>
#include <stdio.h>

#include <osl/diagnose.h>
#include <osl/mutex.hxx>
#include <osl/thread.h>
#include <rtl/instance.hxx>

#include <uno/threadpool.h>

#include "threadpool.hxx"
#include "thread.hxx"

using namespace ::std;
using namespace ::osl;

namespace cppu_threadpool
{
	struct theDisposedCallerAdmin :
		public rtl::StaticWithInit< DisposedCallerAdminHolder, theDisposedCallerAdmin >
	{
		DisposedCallerAdminHolder operator () () {
			return DisposedCallerAdminHolder(new DisposedCallerAdmin());
		}
	};

	DisposedCallerAdminHolder DisposedCallerAdmin::getInstance()
	{
		return theDisposedCallerAdmin::get();
	}

	DisposedCallerAdmin::~DisposedCallerAdmin()
	{
#if OSL_DEBUG_LEVEL > 1
		if( !m_lst.empty() )
		{
			printf( "DisposedCallerList : %lu left\n" , static_cast<unsigned long>(m_lst.size( )));
		}
#endif
	}

	void DisposedCallerAdmin::dispose( sal_Int64 nDisposeId )
	{
		MutexGuard guard( m_mutex );
		m_lst.push_back( nDisposeId );
	}

	void DisposedCallerAdmin::stopDisposing( sal_Int64 nDisposeId )
	{
		MutexGuard guard( m_mutex );
		for( DisposedCallerList::iterator ii = m_lst.begin() ;
			 ii != m_lst.end() ;
			 ++ ii )
		{
			if( (*ii) == nDisposeId )
			{
				m_lst.erase( ii );
				break;
			}
		}
	}

	sal_Bool DisposedCallerAdmin::isDisposed( sal_Int64 nDisposeId )
	{
		MutexGuard guard( m_mutex );
		for( DisposedCallerList::iterator ii = m_lst.begin() ;
			 ii != m_lst.end() ;
			 ++ ii )
		{
			if( (*ii) == nDisposeId )
			{
				return sal_True;
			}
		}
		return sal_False;
	}


	//-------------------------------------------------------------------------------

	struct theThreadPool :
		public rtl::StaticWithInit< ThreadPoolHolder, theThreadPool >
	{
		ThreadPoolHolder operator () () {
			ThreadPoolHolder aRet(new ThreadPool());
			return aRet;
		}
	};

	ThreadPool::ThreadPool()
	{
        	m_DisposedCallerAdmin = DisposedCallerAdmin::getInstance();
	}

	ThreadPool::~ThreadPool()
	{
#if OSL_DEBUG_LEVEL > 1
		if( m_mapQueue.size() )
		{
			printf( "ThreadIdHashMap : %lu left\n" , static_cast<unsigned long>(m_mapQueue.size()) );
		}
#endif
	}
	ThreadPoolHolder ThreadPool::getInstance()
	{
		return theThreadPool::get();
	}


	void ThreadPool::dispose( sal_Int64 nDisposeId )
	{
		if( nDisposeId )
		{
			m_DisposedCallerAdmin->dispose( nDisposeId );

			MutexGuard guard( m_mutex );
			for( ThreadIdHashMap::iterator ii = m_mapQueue.begin() ;
				 ii != m_mapQueue.end();
				 ++ii)
			{
				if( (*ii).second.first )
				{
					(*ii).second.first->dispose( nDisposeId );
				}
				if( (*ii).second.second )
				{
					(*ii).second.second->dispose( nDisposeId );
				}
			}
		}
		else
		{
			{
				MutexGuard guard( m_mutexWaitingThreadList );
				for( WaitingThreadList::iterator ii = m_lstThreads.begin() ;
					 ii != m_lstThreads.end() ;
					 ++ ii )
				{
					// wake the threads up
					osl_setCondition( (*ii)->condition );
				}
			}
			ThreadAdmin::getInstance()->join();
		}
	}

	void ThreadPool::stopDisposing( sal_Int64 nDisposeId )
	{
		m_DisposedCallerAdmin->stopDisposing( nDisposeId );
	}

	/******************
	 * This methods lets the thread wait a certain amount of time. If within this timespan
	 * a new request comes in, this thread is reused. This is done only to improve performance,
	 * it is not required for threadpool functionality.
	 ******************/
	void ThreadPool::waitInPool( ORequestThread * pThread )
	{
		struct WaitingThread waitingThread;
		waitingThread.condition = osl_createCondition();
		waitingThread.thread = pThread;
		{
			MutexGuard guard( m_mutexWaitingThreadList );
			m_lstThreads.push_front( &waitingThread );
		}

		// let the thread wait 2 seconds
		TimeValue time = { 2 , 0 };
		osl_waitCondition( waitingThread.condition , &time );

		{
			MutexGuard guard ( m_mutexWaitingThreadList );
			if( waitingThread.thread )
			{
				// thread wasn't reused, remove it from the list
				WaitingThreadList::iterator ii = find(
					m_lstThreads.begin(), m_lstThreads.end(), &waitingThread );
				OSL_ASSERT( ii != m_lstThreads.end() );
				m_lstThreads.erase( ii );
			}
		}

		osl_destroyCondition( waitingThread.condition );
	}

	void ThreadPool::createThread( JobQueue *pQueue ,
								   const ByteSequence &aThreadId,
								   sal_Bool bAsynchron )
	{
		sal_Bool bCreate = sal_True;
		{
			// Can a thread be reused ?
			MutexGuard guard( m_mutexWaitingThreadList );
			if( ! m_lstThreads.empty() )
			{
				// inform the thread and let it go
				struct WaitingThread *pWaitingThread = m_lstThreads.back();
				pWaitingThread->thread->setTask( pQueue , aThreadId , bAsynchron );
				pWaitingThread->thread = 0;

				// remove from list
				m_lstThreads.pop_back();

				// let the thread go
				osl_setCondition( pWaitingThread->condition );
				bCreate = sal_False;
			}
		}

		if( bCreate )
		{
			ORequestThread *pThread =
				new ORequestThread( pQueue , aThreadId, bAsynchron);
			// deletes itself !
			pThread->create();
		}
	}

	sal_Bool ThreadPool::revokeQueue( const ByteSequence &aThreadId, sal_Bool bAsynchron )
	{
		MutexGuard guard( m_mutex );

		ThreadIdHashMap::iterator ii = m_mapQueue.find( aThreadId );
		OSL_ASSERT( ii != m_mapQueue.end() );

		if( bAsynchron )
		{
			if( ! (*ii).second.second->isEmpty() )
			{
				// another thread has put something into the queue
				return sal_False;
			}

			(*ii).second.second = 0;
			if( (*ii).second.first )
			{
				// all oneway request have been processed, now
				// synchronus requests may go on
				(*ii).second.first->resume();
			}
		}
		else
		{
			if( ! (*ii).second.first->isEmpty() )
			{
				// another thread has put something into the queue
				return sal_False;
			}
			(*ii).second.first = 0;
		}

		if( 0 == (*ii).second.first && 0 == (*ii).second.second )
		{
			m_mapQueue.erase( ii );
		}

		return sal_True;
	}


	void ThreadPool::addJob(
		const ByteSequence &aThreadId ,
		sal_Bool bAsynchron,
		void *pThreadSpecificData,
		RequestFun * doRequest )
	{
		sal_Bool bCreateThread = sal_False;
		JobQueue *pQueue = 0;
		{
			MutexGuard guard( m_mutex );

			ThreadIdHashMap::iterator ii = m_mapQueue.find( aThreadId );

			if( ii == m_mapQueue.end() )
			{
				m_mapQueue[ aThreadId ] = pair < JobQueue * , JobQueue * > ( 0 , 0 );
				ii = m_mapQueue.find( aThreadId );
				OSL_ASSERT( ii != m_mapQueue.end() );
			}

			if( bAsynchron )
			{
				if( ! (*ii).second.second )
				{
					(*ii).second.second = new JobQueue();
					bCreateThread = sal_True;
				}
				pQueue = (*ii).second.second;
			}
			else
			{
				if( ! (*ii).second.first )
				{
					(*ii).second.first = new JobQueue();
					bCreateThread = sal_True;
				}
				pQueue = (*ii).second.first;

				if( (*ii).second.second && ( (*ii).second.second->isBusy() ) )
				{
					pQueue->suspend();
				}
			}
			pQueue->add( pThreadSpecificData , doRequest );
		}

		if( bCreateThread )
		{
			createThread( pQueue , aThreadId , bAsynchron);
		}
	}

	void ThreadPool::prepare( const ByteSequence &aThreadId )
	{
		MutexGuard guard( m_mutex );

		ThreadIdHashMap::iterator ii = m_mapQueue.find( aThreadId );

		if( ii == m_mapQueue.end() )
		{
			JobQueue *p = new JobQueue();
			m_mapQueue[ aThreadId ] = pair< JobQueue * , JobQueue * > ( p , 0 );
		}
		else if( 0 == (*ii).second.first )
		{
			(*ii).second.first = new JobQueue();
		}
	}

	void * ThreadPool::enter( const ByteSequence & aThreadId , sal_Int64 nDisposeId )
	{
		JobQueue *pQueue = 0;
		{
			MutexGuard guard( m_mutex );

			ThreadIdHashMap::iterator ii = m_mapQueue.find( aThreadId );

			OSL_ASSERT( ii != m_mapQueue.end() );
			pQueue = (*ii).second.first;
		}

		OSL_ASSERT( pQueue );
		void *pReturn = pQueue->enter( nDisposeId );

		if( pQueue->isCallstackEmpty() )
		{
			if( revokeQueue( aThreadId , sal_False) )
			{
				// remove queue
				delete pQueue;
			}
		}
		return pReturn;
	}
}


using namespace cppu_threadpool;

struct uno_ThreadPool_Equal
{
	sal_Bool operator () ( const uno_ThreadPool &a , const uno_ThreadPool &b ) const
		{
			return a == b;
		}
};

struct uno_ThreadPool_Hash
{
	sal_Size operator () ( const uno_ThreadPool &a  )  const
		{
			return (sal_Size) a;
		}
};



typedef ::std::hash_map< uno_ThreadPool, ThreadPoolHolder, uno_ThreadPool_Hash, uno_ThreadPool_Equal > ThreadpoolHashSet;

static ThreadpoolHashSet *g_pThreadpoolHashSet;

struct _uno_ThreadPool
{
	sal_Int32 dummy;
};

extern "C" uno_ThreadPool SAL_CALL
uno_threadpool_create() SAL_THROW_EXTERN_C()
{
	MutexGuard guard( Mutex::getGlobalMutex() );
	if( ! g_pThreadpoolHashSet )
	{
		g_pThreadpoolHashSet = new ThreadpoolHashSet();
	}

	// Just ensure that the handle is unique in the process (via heap)
	uno_ThreadPool h = new struct _uno_ThreadPool;
	g_pThreadpoolHashSet->insert( ThreadpoolHashSet::value_type(h, ThreadPool::getInstance()) );
	return h;
}

extern "C" void SAL_CALL
uno_threadpool_attach( uno_ThreadPool ) SAL_THROW_EXTERN_C()
{
	sal_Sequence *pThreadId = 0;
	uno_getIdOfCurrentThread( &pThreadId );
	ThreadPool::getInstance()->prepare( pThreadId );
	rtl_byte_sequence_release( pThreadId );
	uno_releaseIdFromCurrentThread();
}

extern "C" void SAL_CALL
uno_threadpool_enter( uno_ThreadPool hPool , void **ppJob )
	SAL_THROW_EXTERN_C()
{
	sal_Sequence *pThreadId = 0;
	uno_getIdOfCurrentThread( &pThreadId );
	*ppJob =
		ThreadPool::getInstance()->enter(
            pThreadId,
            sal::static_int_cast< sal_Int64 >(
                reinterpret_cast< sal_IntPtr >(hPool)) );
	rtl_byte_sequence_release( pThreadId );
	uno_releaseIdFromCurrentThread();
}

extern "C" void SAL_CALL
uno_threadpool_detach( uno_ThreadPool ) SAL_THROW_EXTERN_C()
{
	// we might do here some tiding up in case a thread called attach but never detach
}

extern "C" void SAL_CALL
uno_threadpool_putJob(
	uno_ThreadPool,
	sal_Sequence *pThreadId,
	void *pJob,
	void ( SAL_CALL * doRequest ) ( void *pThreadSpecificData ),
	sal_Bool bIsOneway ) SAL_THROW_EXTERN_C()
{
	ThreadPool::getInstance()->addJob( pThreadId, bIsOneway, pJob ,doRequest );
}

extern "C" void SAL_CALL
uno_threadpool_dispose( uno_ThreadPool hPool ) SAL_THROW_EXTERN_C()
{
	ThreadPool::getInstance()->dispose(
        sal::static_int_cast< sal_Int64 >(
            reinterpret_cast< sal_IntPtr >(hPool)) );
}

extern "C" void SAL_CALL
uno_threadpool_destroy( uno_ThreadPool hPool ) SAL_THROW_EXTERN_C()
{
	ThreadPool::getInstance()->stopDisposing(
        sal::static_int_cast< sal_Int64 >(
            reinterpret_cast< sal_IntPtr >(hPool)) );

	if( hPool )
	{
		// special treatment for 0 !
		OSL_ASSERT( g_pThreadpoolHashSet );

		MutexGuard guard( Mutex::getGlobalMutex() );

		ThreadpoolHashSet::iterator ii = g_pThreadpoolHashSet->find( hPool );
		OSL_ASSERT( ii != g_pThreadpoolHashSet->end() );
		g_pThreadpoolHashSet->erase( ii );
		delete hPool;

		if( g_pThreadpoolHashSet->empty() )
		{
			delete g_pThreadpoolHashSet;
			g_pThreadpoolHashSet = 0;
		}
	}
}