/// <summary>
/// Creates a new connection to replace an existing connection
/// </summary>
/// <param name="owningObject">Outer connection that currently owns <paramref name="oldConnection"/></param>
/// <param name="userOptions">Options used to create the new connection</param>
/// <param name="oldConnection">Inner connection that will be replaced</param>
/// <returns>A new inner connection that is attached to the <paramref name="owningObject"/></returns>
internal DbConnectionInternal ReplaceConnection(DbConnection owningObject, DbConnectionOptions userOptions, DbConnectionInternal oldConnection)
{
DbConnectionInternal newConnection = UserCreateRequest(owningObject, userOptions, oldConnection);
if (newConnection != null)
{
PrepareConnection(owningObject, newConnection);
oldConnection.PrepareForReplaceConnection();
oldConnection.DeactivateConnection();
oldConnection.Dispose();
}
return(newConnection);
}
internal bool TryGetConnection(DbConnection owningObject, TaskCompletionSource <DbConnectionInternal> retry, DbConnectionOptions userOptions, out DbConnectionInternal connection)
{
uint waitForMultipleObjectsTimeout = 0;
bool allowCreate = false;
if (retry == null)
{
waitForMultipleObjectsTimeout = (uint)CreationTimeout;
// Set the wait timeout to INFINITE (-1) if the SQL connection timeout is 0 (== infinite)
if (waitForMultipleObjectsTimeout == 0)
{
waitForMultipleObjectsTimeout = unchecked ((uint)Timeout.Infinite);
}
allowCreate = true;
}
if (_state != State.Running)
{
connection = null;
return(true);
}
bool onlyOneCheckConnection = true;
if (TryGetConnection(owningObject, waitForMultipleObjectsTimeout, allowCreate, onlyOneCheckConnection, userOptions, out connection))
{
return(true);
}
else if (retry == null)
{
// timed out on a sync call
return(true);
}
var pendingGetConnection =
new PendingGetConnection(
CreationTimeout == 0 ? Timeout.Infinite : ADP.TimerCurrent() + ADP.TimerFromSeconds(CreationTimeout / 1000),
owningObject,
retry,
userOptions);
_pendingOpens.Enqueue(pendingGetConnection);
// it is better to StartNew too many times than not enough
if (_pendingOpensWaiting == 0)
{
Thread waitOpenThread = new Thread(WaitForPendingOpen);
waitOpenThread.IsBackground = true;
waitOpenThread.Start();
}
connection = null;
return(false);
}
private bool TryGetConnection(DbConnection owningObject, uint waitForMultipleObjectsTimeout, bool allowCreate, bool onlyOneCheckConnection, DbConnectionOptions userOptions, out DbConnectionInternal connection)
{
DbConnectionInternal obj = null;
if (null == obj)
{
Interlocked.Increment(ref _waitCount);
do
{
int waitResult = BOGUS_HANDLE;
try
{
try
{
}
finally
{
waitResult = WaitHandle.WaitAny(_waitHandles.GetHandles(allowCreate), unchecked ((int)waitForMultipleObjectsTimeout));
}
// From the WaitAny docs: "If more than one object became signaled during
// the call, this is the array index of the signaled object with the
// smallest index value of all the signaled objects." This is important
// so that the free object signal will be returned before a creation
// signal.
switch (waitResult)
{
case WaitHandle.WaitTimeout:
Interlocked.Decrement(ref _waitCount);
connection = null;
return(false);
case ERROR_HANDLE:
// Throw the error that PoolCreateRequest stashed.
Interlocked.Decrement(ref _waitCount);
throw TryCloneCachedException();
case CREATION_HANDLE:
try
{
obj = UserCreateRequest(owningObject, userOptions);
}
catch
{
if (null == obj)
{
Interlocked.Decrement(ref _waitCount);
}
throw;
}
finally
{
// Ensure that we release this waiter, regardless
// of any exceptions that may be thrown.
if (null != obj)
{
Interlocked.Decrement(ref _waitCount);
}
}
if (null == obj)
{
// If we were not able to create an object, check to see if
// we reached MaxPoolSize. If so, we will no longer wait on
// the CreationHandle, but instead wait for a free object or
// the timeout.
if (Count >= MaxPoolSize && 0 != MaxPoolSize)
{
if (!ReclaimEmancipatedObjects())
{
// modify handle array not to wait on creation mutex anymore
Debug.Assert(2 == CREATION_HANDLE, "creation handle changed value");
allowCreate = false;
}
}
}
break;
case SEMAPHORE_HANDLE:
//
// guaranteed available inventory
//
Interlocked.Decrement(ref _waitCount);
obj = GetFromGeneralPool();
if ((obj != null) && (!obj.IsConnectionAlive()))
{
DestroyObject(obj);
obj = null; // Setting to null in case creating a new object fails
if (onlyOneCheckConnection)
{
if (_waitHandles.CreationSemaphore.WaitOne(unchecked ((int)waitForMultipleObjectsTimeout)))
{
try
{
obj = UserCreateRequest(owningObject, userOptions);
}
finally
{
_waitHandles.CreationSemaphore.Release(1);
}
}
else
{
// Timeout waiting for creation semaphore - return null
connection = null;
return(false);
}
}
}
break;
default:
Interlocked.Decrement(ref _waitCount);
throw ADP.InternalError(ADP.InternalErrorCode.UnexpectedWaitAnyResult);
}
}
finally
{
if (CREATION_HANDLE == waitResult)
{
_waitHandles.CreationSemaphore.Release(1);
}
}
} while (null == obj);
}
if (null != obj)
{
PrepareConnection(owningObject, obj);
}
connection = obj;
return(true);
}
private void WaitForPendingOpen()
{
PendingGetConnection next;
do
{
bool started = false;
try
{
try { }
finally
{
started = Interlocked.CompareExchange(ref _pendingOpensWaiting, 1, 0) == 0;
}
if (!started)
{
return;
}
while (_pendingOpens.TryDequeue(out next))
{
if (next.Completion.Task.IsCompleted)
{
continue;
}
uint delay;
if (next.DueTime == Timeout.Infinite)
{
delay = unchecked ((uint)Timeout.Infinite);
}
else
{
delay = (uint)Math.Max(ADP.TimerRemainingMilliseconds(next.DueTime), 0);
}
DbConnectionInternal connection = null;
bool timeout = false;
Exception caughtException = null;
try
{
bool allowCreate = true;
bool onlyOneCheckConnection = false;
timeout = !TryGetConnection(next.Owner, delay, allowCreate, onlyOneCheckConnection, next.UserOptions, out connection);
}
catch (Exception e)
{
caughtException = e;
}
if (caughtException != null)
{
next.Completion.TrySetException(caughtException);
}
else if (timeout)
{
next.Completion.TrySetException(ADP.ExceptionWithStackTrace(ADP.PooledOpenTimeout()));
}
else
{
Debug.Assert(connection != null, "connection should never be null in success case");
if (!next.Completion.TrySetResult(connection))
{
// if the completion was cancelled, lets try and get this connection back for the next try
PutObject(connection, next.Owner);
}
}
}
}
finally
{
if (started)
{
Interlocked.Exchange(ref _pendingOpensWaiting, 0);
}
}
} while (_pendingOpens.TryPeek(out next));
}
private void DeactivateObject(DbConnectionInternal obj)
{
obj.DeactivateConnection();
bool returnToGeneralPool = false;
bool destroyObject = false;
if (obj.IsConnectionDoomed)
{
// the object is not fit for reuse -- just dispose of it.
destroyObject = true;
}
else
{
// NOTE: constructor should ensure that current state cannot be State.Initializing, so it can only
// be State.Running or State.ShuttingDown
Debug.Assert(_state == State.Running || _state == State.ShuttingDown);
lock (obj)
{
// A connection with a delegated transaction cannot currently
// be returned to a different customer until the transaction
// actually completes, so we send it into Stasis -- the SysTx
// transaction object will ensure that it is owned (not lost),
// and it will be certain to put it back into the pool.
if (_state == State.ShuttingDown)
{
// connection is being closed and the pool has been marked as shutting
// down, so destroy this object.
destroyObject = true;
}
else
{
if (obj.CanBePooled)
{
// We must put this connection into the transacted pool
// while inside a lock to prevent a race condition with
// the transaction asyncronously completing on a second
// thread.
// return to general pool
returnToGeneralPool = true;
}
else
{
// object is not fit for reuse -- just dispose of it
destroyObject = true;
}
}
}
}
if (returnToGeneralPool)
{
// Only push the connection into the general pool if we didn't
// already push it onto the transacted pool, put it into stasis,
// or want to destroy it.
Debug.Assert(destroyObject == false);
PutNewObject(obj);
}
else if (destroyObject)
{
DestroyObject(obj);
QueuePoolCreateRequest();
}
//-------------------------------------------------------------------------------------
// postcondition
// ensure that the connection was processed
Debug.Assert(
returnToGeneralPool == true || destroyObject == true);
}
private DbConnectionInternal CreateObject(DbConnection owningObject, DbConnectionOptions userOptions, DbConnectionInternal oldConnection)
{
DbConnectionInternal newObj = null;
try
{
newObj = _connectionFactory.CreatePooledConnection(this, owningObject, _connectionPoolGroup.ConnectionOptions, _connectionPoolGroup.PoolKey, userOptions);
if (null == newObj)
{
throw ADP.InternalError(ADP.InternalErrorCode.CreateObjectReturnedNull); // CreateObject succeeded, but null object
}
if (!newObj.CanBePooled)
{
throw ADP.InternalError(ADP.InternalErrorCode.NewObjectCannotBePooled); // CreateObject succeeded, but non-poolable object
}
newObj.PrePush(null);
lock (_objectList)
{
if ((oldConnection != null) && (oldConnection.Pool == this))
{
_objectList.Remove(oldConnection);
}
_objectList.Add(newObj);
_totalObjects = _objectList.Count;
}
// If the old connection belonged to another pool, we need to remove it from that
if (oldConnection != null)
{
var oldConnectionPool = oldConnection.Pool;
if (oldConnectionPool != null && oldConnectionPool != this)
{
Debug.Assert(oldConnectionPool._state == State.ShuttingDown, "Old connections pool should be shutting down");
lock (oldConnectionPool._objectList)
{
oldConnectionPool._objectList.Remove(oldConnection);
oldConnectionPool._totalObjects = oldConnectionPool._objectList.Count;
}
}
}
// Reset the error wait:
_errorWait = ERROR_WAIT_DEFAULT;
}
catch (Exception e)
{
if (!ADP.IsCatchableExceptionType(e))
{
throw;
}
newObj = null; // set to null, so we do not return bad new object
// Failed to create instance
_resError = e;
// Make sure the timer starts even if ThreadAbort occurs after setting the ErrorEvent.
// timer allocation has to be done out of CER block
Timer t = new Timer(new TimerCallback(this.ErrorCallback), null, Timeout.Infinite, Timeout.Infinite);
bool timerIsNotDisposed;
try { }
finally
{
_waitHandles.ErrorEvent.Set();
_errorOccurred = true;
// Enable the timer.
// Note that the timer is created to allow periodic invocation. If ThreadAbort occurs in the middle of ErrorCallback,
// the timer will restart. Otherwise, the timer callback (ErrorCallback) destroys the timer after resetting the error to avoid second callback.
_errorTimer = t;
timerIsNotDisposed = t.Change(_errorWait, _errorWait);
}
Debug.Assert(timerIsNotDisposed, "ErrorCallback timer has been disposed");
if (30000 < _errorWait)
{
_errorWait = 60000;
}
else
{
_errorWait *= 2;
}
throw;
}
return(newObj);
}
private DbConnectionInternal UserCreateRequest(DbConnection owningObject, DbConnectionOptions userOptions, DbConnectionInternal oldConnection = null)
{
// called by user when they were not able to obtain a free object but
// instead obtained creation mutex
DbConnectionInternal obj = null;
if (ErrorOccurred)
{
throw TryCloneCachedException();
}
else
{
if ((oldConnection != null) || (Count < MaxPoolSize) || (0 == MaxPoolSize))
{
// If we have an odd number of total objects, reclaim any dead objects.
// If we did not find any objects to reclaim, create a new one.
if ((oldConnection != null) || (Count & 0x1) == 0x1 || !ReclaimEmancipatedObjects())
{
obj = CreateObject(owningObject, userOptions, oldConnection);
}
}
return(obj);
}
}
private bool ReclaimEmancipatedObjects()
{
bool emancipatedObjectFound = false;
List <DbConnectionInternal> reclaimedObjects = new List <DbConnectionInternal>();
int count;
lock (_objectList)
{
count = _objectList.Count;
for (int i = 0; i < count; ++i)
{
DbConnectionInternal obj = _objectList[i];
if (null != obj)
{
bool locked = false;
try
{
Monitor.TryEnter(obj, ref locked);
if (locked)
{ // avoid race condition with PrePush/PostPop and IsEmancipated
if (obj.IsEmancipated)
{
// Inside the lock, we want to do as little
// as possible, so we simply mark the object
// as being in the pool, but hand it off to
// an out of pool list to be deactivated,
// etc.
obj.PrePush(null);
reclaimedObjects.Add(obj);
}
}
}
finally
{
if (locked)
{
Monitor.Exit(obj);
}
}
}
}
}
// NOTE: we don't want to call DeactivateObject while we're locked,
// because it can make roundtrips to the server and this will block
// object creation in the pooler. Instead, we queue things we need
// to do up, and process them outside the lock.
count = reclaimedObjects.Count;
for (int i = 0; i < count; ++i)
{
DbConnectionInternal obj = reclaimedObjects[i];
emancipatedObjectFound = true;
DeactivateObject(obj);
}
return(emancipatedObjectFound);
}