Exemplo n.º 1
0
ipc_port_t
retrieve_thread_self_fast(
	thread_t		thread)
{
	register ipc_port_t port;

	assert(thread == current_thread());

	thread_mtx_lock(thread);

	assert(thread->ith_self != IP_NULL);

	if ((port = thread->ith_sself) == thread->ith_self) {
		/* no interposing */

		ip_lock(port);
		assert(ip_active(port));
		ip_reference(port);
		port->ip_srights++;
		ip_unlock(port);
	}
	else
		port = ipc_port_copy_send(port);

	thread_mtx_unlock(thread);

	return port;
}
Exemplo n.º 2
0
ipc_port_t
ipc_port_lookup_notify(
	ipc_space_t		space,
	mach_port_name_t	name)
{
	ipc_port_t port;
	ipc_entry_t entry;

	assert(is_active(space));

	entry = ipc_entry_lookup(space, name);
	if (entry == IE_NULL)
		return IP_NULL;
	if ((entry->ie_bits & MACH_PORT_TYPE_RECEIVE) == 0)
		return IP_NULL;

	port = (ipc_port_t) entry->ie_object;
	assert(port != IP_NULL);

	ip_lock(port);
	assert(ip_active(port));
	assert(port->ip_receiver_name == name);
	assert(port->ip_receiver == space);

	ip_reference(port);
	port->ip_sorights++;
	ip_unlock(port);

	return port;
}
Exemplo n.º 3
0
EXTERN io_object_t
iokit_lookup_connect_ref(io_object_t connectRef, ipc_space_t space)
{
	io_object_t obj = NULL;

	if (connectRef && MACH_PORT_VALID(CAST_MACH_PORT_TO_NAME(connectRef))) {
		ipc_port_t port;
		kern_return_t kr;

		kr = ipc_object_translate(space, CAST_MACH_PORT_TO_NAME(connectRef), MACH_PORT_RIGHT_SEND, (ipc_object_t *)&port);

		if (kr == KERN_SUCCESS) {
			assert(IP_VALID(port));

			ip_reference(port);
			ip_unlock(port);

			iokit_lock_port(port);
			if (ip_active(port) && (ip_kotype(port) == IKOT_IOKIT_CONNECT)) {
				obj = (io_object_t) port->ip_kobject;
				iokit_add_connect_reference(obj);
			}
			iokit_unlock_port(port);

			ip_release(port);
		}
	}

	return obj;
}
Exemplo n.º 4
0
ipc_port_t
retrieve_task_self_fast(
	register task_t		task)
{
	register ipc_port_t port;

	assert(task == current_task());

	itk_lock(task);
	assert(task->itk_self != IP_NULL);

	if ((port = task->itk_sself) == task->itk_self) {
		/* no interposing */

		ip_lock(port);
		assert(ip_active(port));
		ip_reference(port);
		port->ip_srights++;
		ip_unlock(port);
	} else
		port = ipc_port_copy_send(port);
	itk_unlock(task);

	return port;
}
Exemplo n.º 5
0
ipc_port_t
ipc_port_make_sonce_locked(
	ipc_port_t	port)
{
	assert(ip_active(port));
	port->ip_sorights++;
	ip_reference(port);
	return port;
}
Exemplo n.º 6
0
void
exception(
	integer_t _exception, 
	integer_t code, 
	integer_t subcode)
{
	ipc_thread_t self = current_thread();
	ipc_port_t exc_port;

	if (_exception == KERN_SUCCESS)
		panic("exception");

	/*
	 *	Optimized version of retrieve_thread_exception.
	 */

	ith_lock(self);
	assert(self->ith_self != IP_NULL);
	exc_port = self->ith_exception;
	if (!IP_VALID(exc_port)) {
		ith_unlock(self);
		exception_try_task(_exception, code, subcode);
		/*NOTREACHED*/
	}

	ip_lock(exc_port);
	ith_unlock(self);
	if (!ip_active(exc_port)) {
		ip_unlock(exc_port);
		exception_try_task(_exception, code, subcode);
		/*NOTREACHED*/
	}

	/*
	 *	Make a naked send right for the exception port.
	 */

	ip_reference(exc_port);
	exc_port->ip_srights++;
	ip_unlock(exc_port);

	/*
	 *	If this exception port doesn't work,
	 *	we will want to try the task's exception port.
	 *	Indicate this by saving the exception state.
	 */

	self->ith_exc = _exception;
	self->ith_exc_code = code;
	self->ith_exc_subcode = subcode;

	exception_raise(exc_port,
			retrieve_thread_self_fast(self),
			retrieve_task_self_fast(self->task),
			_exception, code, subcode);
	/*NOTREACHED*/
}
Exemplo n.º 7
0
/*
 *	Routine:	ipc_port_make_send_locked
 *	Purpose:
 *		Make a naked send right from a receive right.
 *
 *	Conditions:
 *		port locked and active.
 */
ipc_port_t
ipc_port_make_send_locked(
	ipc_port_t	port)
{
	assert(ip_active(port));
	port->ip_mscount++;
	port->ip_srights++;
	ip_reference(port);
	return port;
}
Exemplo n.º 8
0
/*
 *	Routine:	convert_mig_object_to_port [interface]
 *	Purpose:
 *		Base implementation of MIG outtrans routine to convert from
 *		a mig object reference to a new send right on the object's
 *		port.  The object reference is consumed.
 *	Returns:
 *		IP_NULL - Null MIG object supplied
 *		Otherwise, a newly made send right for the port
 *	Conditions:
 *		Nothing locked.
 */
ipc_port_t
convert_mig_object_to_port(
	mig_object_t	mig_object)
{
	ipc_port_t	port;
	boolean_t	deallocate = TRUE;

	if (mig_object == MIG_OBJECT_NULL)
		return IP_NULL;

	port = mig_object->port;
	while ((port == IP_NULL) ||
	       ((port = ipc_port_make_send(port)) == IP_NULL)) {
		ipc_port_t	previous;

		/*
		 * Either the port was never set up, or it was just
		 * deallocated out from under us by the no-senders
		 * processing.  In either case, we must:
		 *	Attempt to make one
		 * 	Arrange for no senders
		 *	Try to atomically register it with the object
		 *		Destroy it if we are raced.
		 */
		port = ipc_port_alloc_kernel();
		ip_lock(port);
		ipc_kobject_set_atomically(port,
					   (ipc_kobject_t) mig_object,
					   IKOT_MIG);

		/* make a sonce right for the notification */
		port->ip_sorights++;
		ip_reference(port);

		ipc_port_nsrequest(port, 1, port, &previous);
		/* port unlocked */

		assert(previous == IP_NULL);

		if (OSCompareAndSwapPtr((void *)IP_NULL, (void *)port,
											(void * volatile *)&mig_object->port)) {
			deallocate = FALSE;
		} else {
			ipc_port_dealloc_kernel(port);
			port = mig_object->port;
		}
	}

	if (deallocate)
		mig_object->pVtbl->Release((IMIGObject *)mig_object);

	return (port);
}
Exemplo n.º 9
0
void
exception_try_task(
	integer_t _exception, 
	integer_t code, 
	integer_t subcode)
{
	ipc_thread_t self = current_thread();
	task_t task = self->task;
	ipc_port_t exc_port;

	/*
	 *	Optimized version of retrieve_task_exception.
	 */

	itk_lock(task);
	assert(task->itk_self != IP_NULL);
	exc_port = task->itk_exception;
	if (!IP_VALID(exc_port)) {
		itk_unlock(task);
		exception_no_server();
		/*NOTREACHED*/
	}

	ip_lock(exc_port);
	itk_unlock(task);
	if (!ip_active(exc_port)) {
		ip_unlock(exc_port);
		exception_no_server();
		/*NOTREACHED*/
	}

	/*
	 *	Make a naked send right for the exception port.
	 */

	ip_reference(exc_port);
	exc_port->ip_srights++;
	ip_unlock(exc_port);

	/*
	 *	This is the thread's last chance.
	 *	Clear the saved exception state.
	 */

	self->ith_exc = KERN_SUCCESS;

	exception_raise(exc_port,
			retrieve_thread_self_fast(self),
			retrieve_task_self_fast(task),
			_exception, code, subcode);
	/*NOTREACHED*/
}
Exemplo n.º 10
0
ipc_port_t
ipc_port_make_sonce(
	ipc_port_t	port)
{
	assert(IP_VALID(port));

	ip_lock(port);
	assert(ip_active(port));
	port->ip_sorights++;
	ip_reference(port);
	ip_unlock(port);

	return port;
}
Exemplo n.º 11
0
boolean_t
mig_object_no_senders(
	ipc_port_t		port,
	mach_port_mscount_t	mscount)
{
	mig_object_t		mig_object;

	ip_lock(port);
	if (port->ip_mscount > mscount) {
		ipc_port_t 	previous;

		/*
		 * Somebody created new send rights while the
		 * notification was in-flight.  Just create a
		 * new send-once right and re-register with 
		 * the new (higher) mscount threshold.
		 */
		/* make a sonce right for the notification */
		port->ip_sorights++;
		ip_reference(port);
		ipc_port_nsrequest(port, mscount, port, &previous);
		/* port unlocked */

		assert(previous == IP_NULL);
		return (FALSE);
	}

	/*
	 * Clear the port pointer while we have it locked.
	 */
	mig_object = (mig_object_t)port->ip_kobject;
	mig_object->port = IP_NULL;

	/*
	 * Bring the sequence number and mscount in
	 * line with ipc_port_destroy assertion.
	 */
	port->ip_mscount = 0;
	port->ip_messages.imq_seqno = 0;
	ipc_port_destroy(port); /* releases lock */
	
	/*
	 * Release the port's reference on the object.
	 */
	mig_object->pVtbl->Release((IMIGObject *)mig_object);
	return (TRUE);
}	
Exemplo n.º 12
0
ipc_port_t
ipc_port_make_sonce(
	ipc_port_t	port)
{
	if (!IP_VALID(port))
		return port;

	ip_lock(port);
	if (ip_active(port)) {
		port->ip_sorights++;
		ip_reference(port);
		ip_unlock(port);
		return port;
	}
	ip_unlock(port);
	return IP_DEAD;
}
Exemplo n.º 13
0
ipc_port_t
ipc_port_copy_send(
	ipc_port_t	port)
{
	ipc_port_t sright;

	if (!IP_VALID(port))
		return port;

	ip_lock(port);
	if (ip_active(port)) {
		assert(port->ip_srights > 0);

		ip_reference(port);
		port->ip_srights++;
		sright = port;
	} else
		sright = IP_DEAD;
	ip_unlock(port);

	return sright;
}
Exemplo n.º 14
0
mach_port_name_t
mk_timer_create_trap(
	__unused struct mk_timer_create_trap_args *args)
{
	mk_timer_t			timer;
	ipc_space_t			myspace = current_space();
	mach_port_name_t	name = MACH_PORT_NULL;
	ipc_port_t			port;
	kern_return_t		result;

	timer = (mk_timer_t)zalloc(mk_timer_zone);
	if (timer == NULL)
		return (MACH_PORT_NULL);

	result = mach_port_allocate_qos(myspace, MACH_PORT_RIGHT_RECEIVE,
														&mk_timer_qos, &name);
	if (result == KERN_SUCCESS)
		result = ipc_port_translate_receive(myspace, name, &port);

	if (result != KERN_SUCCESS) {
		zfree(mk_timer_zone, timer);

		return (MACH_PORT_NULL);
	}

	simple_lock_init(&timer->lock, 0);
	call_entry_setup(&timer->call_entry, mk_timer_expire, timer);
	timer->is_armed = timer->is_dead = FALSE;
	timer->active = 0;

	timer->port = port;
	ipc_kobject_set_atomically(port, (ipc_kobject_t)timer, IKOT_TIMER);

	port->ip_srights++;
	ip_reference(port);
	ip_unlock(port);

	return (name);
}
Exemplo n.º 15
0
kern_return_t
ipc_right_copyin(
	ipc_space_t		space,
	mach_port_t		name,
	ipc_entry_t		entry,
	mach_msg_type_name_t	msgt_name,
	boolean_t		deadok,
	ipc_object_t		*objectp,
	ipc_port_t		*sorightp)
{
	ipc_entry_bits_t bits = entry->ie_bits;

	assert(space->is_active);

	switch (msgt_name) {
	    case MACH_MSG_TYPE_MAKE_SEND: {
		ipc_port_t port;

		if ((bits & MACH_PORT_TYPE_RECEIVE) == 0)
			goto invalid_right;

		port = (ipc_port_t) entry->ie_object;
		assert(port != IP_NULL);

		ip_lock(port);
		assert(ip_active(port));
		assert(port->ip_receiver_name == name);
		assert(port->ip_receiver == space);

		port->ip_mscount++;
		port->ip_srights++;
		ip_reference(port);
		ip_unlock(port);

		*objectp = (ipc_object_t) port;
		*sorightp = IP_NULL;
		break;
	    }

	    case MACH_MSG_TYPE_MAKE_SEND_ONCE: {
		ipc_port_t port;

		if ((bits & MACH_PORT_TYPE_RECEIVE) == 0)
			goto invalid_right;

		port = (ipc_port_t) entry->ie_object;
		assert(port != IP_NULL);

		ip_lock(port);
		assert(ip_active(port));
		assert(port->ip_receiver_name == name);
		assert(port->ip_receiver == space);

		port->ip_sorights++;
		ip_reference(port);
		ip_unlock(port);

		*objectp = (ipc_object_t) port;
		*sorightp = IP_NULL;
		break;
	    }

	    case MACH_MSG_TYPE_MOVE_RECEIVE: {
		ipc_port_t port;
		ipc_port_t dnrequest = IP_NULL;

		if ((bits & MACH_PORT_TYPE_RECEIVE) == 0)
			goto invalid_right;

		port = (ipc_port_t) entry->ie_object;
		assert(port != IP_NULL);

		ip_lock(port);
		assert(ip_active(port));
		assert(port->ip_receiver_name == name);
		assert(port->ip_receiver == space);

		if (bits & MACH_PORT_TYPE_SEND) {
			assert(IE_BITS_TYPE(bits) ==
					MACH_PORT_TYPE_SEND_RECEIVE);
			assert(IE_BITS_UREFS(bits) > 0);
			assert(port->ip_srights > 0);

			entry->ie_name = name;
			ipc_reverse_insert(space, (ipc_object_t) port, entry);

			ip_reference(port);
		} else {
			assert(IE_BITS_TYPE(bits) == MACH_PORT_TYPE_RECEIVE);
			assert(IE_BITS_UREFS(bits) == 0);

			dnrequest = ipc_right_dncancel_macro(space, port,
							     name, entry);

			if (bits & IE_BITS_MAREQUEST)
				ipc_marequest_cancel(space, name);

			entry->ie_object = IO_NULL;
		}
		entry->ie_bits = bits &~ MACH_PORT_TYPE_RECEIVE;

		ipc_port_clear_receiver(port);

		port->ip_receiver_name = MACH_PORT_NULL;
		port->ip_destination = IP_NULL;

		/*
		 *	Clear the protected payload field to retain
		 *	the behavior of mach_msg.
		 */
		ipc_port_flag_protected_payload_clear(port);
		ip_unlock(port);

		*objectp = (ipc_object_t) port;
		*sorightp = dnrequest;
		break;
	    }

	    case MACH_MSG_TYPE_COPY_SEND: {
		ipc_port_t port;

		if (bits & MACH_PORT_TYPE_DEAD_NAME)
			goto copy_dead;

		/* allow for dead send-once rights */

		if ((bits & MACH_PORT_TYPE_SEND_RIGHTS) == 0)
			goto invalid_right;

		assert(IE_BITS_UREFS(bits) > 0);

		port = (ipc_port_t) entry->ie_object;
		assert(port != IP_NULL);

		if (ipc_right_check(space, port, name, entry)) {
			bits = entry->ie_bits;
			goto copy_dead;
		}
		/* port is locked and active */

		if ((bits & MACH_PORT_TYPE_SEND) == 0) {
			assert(IE_BITS_TYPE(bits) == MACH_PORT_TYPE_SEND_ONCE);
			assert(port->ip_sorights > 0);

			ip_unlock(port);
			goto invalid_right;
		}

		assert(port->ip_srights > 0);

		port->ip_srights++;
		ip_reference(port);
		ip_unlock(port);

		*objectp = (ipc_object_t) port;
		*sorightp = IP_NULL;
		break;
	    }

	    case MACH_MSG_TYPE_MOVE_SEND: {
		ipc_port_t port;
		ipc_port_t dnrequest = IP_NULL;

		if (bits & MACH_PORT_TYPE_DEAD_NAME)
			goto move_dead;

		/* allow for dead send-once rights */

		if ((bits & MACH_PORT_TYPE_SEND_RIGHTS) == 0)
			goto invalid_right;

		assert(IE_BITS_UREFS(bits) > 0);

		port = (ipc_port_t) entry->ie_object;
		assert(port != IP_NULL);

		if (ipc_right_check(space, port, name, entry)) {
			bits = entry->ie_bits;
			goto move_dead;
		}
		/* port is locked and active */

		if ((bits & MACH_PORT_TYPE_SEND) == 0) {
			assert(IE_BITS_TYPE(bits) == MACH_PORT_TYPE_SEND_ONCE);
			assert(port->ip_sorights > 0);

			ip_unlock(port);
			goto invalid_right;
		}

		assert(port->ip_srights > 0);

		if (IE_BITS_UREFS(bits) == 1) {
			if (bits & MACH_PORT_TYPE_RECEIVE) {
				assert(port->ip_receiver_name == name);
				assert(port->ip_receiver == space);
				assert(IE_BITS_TYPE(bits) ==
						MACH_PORT_TYPE_SEND_RECEIVE);

				ip_reference(port);
			} else {
				assert(IE_BITS_TYPE(bits) ==
						MACH_PORT_TYPE_SEND);

				dnrequest = ipc_right_dncancel_macro(
						space, port, name, entry);

				ipc_reverse_remove(space, (ipc_object_t) port);

				if (bits & IE_BITS_MAREQUEST)
					ipc_marequest_cancel(space, name);

				entry->ie_object = IO_NULL;
			}
			entry->ie_bits = bits &~
				(IE_BITS_UREFS_MASK|MACH_PORT_TYPE_SEND);
		} else {
			port->ip_srights++;
			ip_reference(port);
			entry->ie_bits = bits-1; /* decrement urefs */
		}

		ip_unlock(port);

		*objectp = (ipc_object_t) port;
		*sorightp = dnrequest;
		break;
	    }

	    case MACH_MSG_TYPE_MOVE_SEND_ONCE: {
		ipc_port_t port;
		ipc_port_t dnrequest;

		if (bits & MACH_PORT_TYPE_DEAD_NAME)
			goto move_dead;

		/* allow for dead send rights */

		if ((bits & MACH_PORT_TYPE_SEND_RIGHTS) == 0)
			goto invalid_right;

		assert(IE_BITS_UREFS(bits) > 0);

		port = (ipc_port_t) entry->ie_object;
		assert(port != IP_NULL);

		if (ipc_right_check(space, port, name, entry)) {
			bits = entry->ie_bits;
			goto move_dead;
		}
		/* port is locked and active */

		if ((bits & MACH_PORT_TYPE_SEND_ONCE) == 0) {
			assert(bits & MACH_PORT_TYPE_SEND);
			assert(port->ip_srights > 0);

			ip_unlock(port);
			goto invalid_right;
		}

		assert(IE_BITS_TYPE(bits) == MACH_PORT_TYPE_SEND_ONCE);
		assert(IE_BITS_UREFS(bits) == 1);
		assert((bits & IE_BITS_MAREQUEST) == 0);
		assert(port->ip_sorights > 0);

		dnrequest = ipc_right_dncancel_macro(space, port, name, entry);
		ip_unlock(port);

		entry->ie_object = IO_NULL;
		entry->ie_bits = bits &~ MACH_PORT_TYPE_SEND_ONCE;

		*objectp = (ipc_object_t) port;
		*sorightp = dnrequest;
		break;
	    }

	    default:
#if MACH_ASSERT
		assert(!"ipc_right_copyin: strange rights");
#else
		panic("ipc_right_copyin: strange rights");
#endif
	}

	return KERN_SUCCESS;

    copy_dead:
	assert(IE_BITS_TYPE(bits) == MACH_PORT_TYPE_DEAD_NAME);
	assert(IE_BITS_UREFS(bits) > 0);
	assert((bits & IE_BITS_MAREQUEST) == 0);
	assert(entry->ie_request == 0);
	assert(entry->ie_object == 0);

	if (!deadok)
		goto invalid_right;

	*objectp = IO_DEAD;
	*sorightp = IP_NULL;
	return KERN_SUCCESS;

    move_dead:
	assert(IE_BITS_TYPE(bits) == MACH_PORT_TYPE_DEAD_NAME);
	assert(IE_BITS_UREFS(bits) > 0);
	assert((bits & IE_BITS_MAREQUEST) == 0);
	assert(entry->ie_request == 0);
	assert(entry->ie_object == 0);

	if (!deadok)
		goto invalid_right;

	if (IE_BITS_UREFS(bits) == 1)
		entry->ie_bits = bits &~ MACH_PORT_TYPE_DEAD_NAME;
	else
		entry->ie_bits = bits-1; /* decrement urefs */

	*objectp = IO_DEAD;
	*sorightp = IP_NULL;
	return KERN_SUCCESS;

    invalid_right:
	return KERN_INVALID_RIGHT;
}
Exemplo n.º 16
0
kern_return_t
ipc_right_copyin_two(
	ipc_space_t	space,
	mach_port_t	name,
	ipc_entry_t	entry,
	ipc_object_t	*objectp,
	ipc_port_t	*sorightp)
{
	ipc_entry_bits_t bits = entry->ie_bits;
	mach_port_urefs_t urefs;
	ipc_port_t port;
	ipc_port_t dnrequest = IP_NULL;

	assert(space->is_active);

	if ((bits & MACH_PORT_TYPE_SEND) == 0)
		goto invalid_right;

	urefs = IE_BITS_UREFS(bits);
	if (urefs < 2)
		goto invalid_right;

	port = (ipc_port_t) entry->ie_object;
	assert(port != IP_NULL);

	if (ipc_right_check(space, port, name, entry)) {
		goto invalid_right;
	}
	/* port is locked and active */

	assert(port->ip_srights > 0);

	if (urefs == 2) {
		if (bits & MACH_PORT_TYPE_RECEIVE) {
			assert(port->ip_receiver_name == name);
			assert(port->ip_receiver == space);
			assert(IE_BITS_TYPE(bits) ==
					MACH_PORT_TYPE_SEND_RECEIVE);

			port->ip_srights++;
			ip_reference(port);
			ip_reference(port);
		} else {
			assert(IE_BITS_TYPE(bits) == MACH_PORT_TYPE_SEND);

			dnrequest = ipc_right_dncancel_macro(space, port,
							     name, entry);

			ipc_reverse_remove(space, (ipc_object_t) port);

			if (bits & IE_BITS_MAREQUEST)
				ipc_marequest_cancel(space, name);

			port->ip_srights++;
			ip_reference(port);
			entry->ie_object = IO_NULL;
		}
		entry->ie_bits = bits &~
			(IE_BITS_UREFS_MASK|MACH_PORT_TYPE_SEND);
	} else {
		port->ip_srights += 2;
		ip_reference(port);
		ip_reference(port);
		entry->ie_bits = bits-2; /* decrement urefs */
	}
	ip_unlock(port);

	*objectp = (ipc_object_t) port;
	*sorightp = dnrequest;
	return KERN_SUCCESS;

    invalid_right:
	return KERN_INVALID_RIGHT;
}
Exemplo n.º 17
0
void
ipc_port_reference(ipc_port_t port)
{
	ip_reference(port);
}
Exemplo n.º 18
0
boolean_t
ipc_port_check_circularity(
	ipc_port_t	port,
	ipc_port_t	dest)
{
	ipc_port_t base;

	assert(port != IP_NULL);
	assert(dest != IP_NULL);

	if (port == dest)
		return TRUE;
	base = dest;

	/*
	 *	First try a quick check that can run in parallel.
	 *	No circularity if dest is not in transit.
	 */

	ip_lock(port);
	if (ip_lock_try(dest)) {
		if (!ip_active(dest) ||
		    (dest->ip_receiver_name != MACH_PORT_NULL) ||
		    (dest->ip_destination == IP_NULL))
			goto not_circular;

		/* dest is in transit; further checking necessary */

		ip_unlock(dest);
	}
	ip_unlock(port);

	ipc_port_multiple_lock(); /* massive serialization */

	/*
	 *	Search for the end of the chain (a port not in transit),
	 *	acquiring locks along the way.
	 */

	for (;;) {
		ip_lock(base);

		if (!ip_active(base) ||
		    (base->ip_receiver_name != MACH_PORT_NULL) ||
		    (base->ip_destination == IP_NULL))
			break;

		base = base->ip_destination;
	}

	/* all ports in chain from dest to base, inclusive, are locked */

	if (port == base) {
		/* circularity detected! */

		ipc_port_multiple_unlock();

		/* port (== base) is in limbo */

		assert(ip_active(port));
		assert(port->ip_receiver_name == MACH_PORT_NULL);
		assert(port->ip_destination == IP_NULL);

		while (dest != IP_NULL) {
			ipc_port_t next;

			/* dest is in transit or in limbo */

			assert(ip_active(dest));
			assert(dest->ip_receiver_name == MACH_PORT_NULL);

			next = dest->ip_destination;
			ip_unlock(dest);
			dest = next;
		}

		return TRUE;
	}

	/*
	 *	The guarantee:  lock port while the entire chain is locked.
	 *	Once port is locked, we can take a reference to dest,
	 *	add port to the chain, and unlock everything.
	 */

	ip_lock(port);
	ipc_port_multiple_unlock();

    not_circular:

	/* port is in limbo */

	assert(ip_active(port));
	assert(port->ip_receiver_name == MACH_PORT_NULL);
	assert(port->ip_destination == IP_NULL);

	ip_reference(dest);
	port->ip_destination = dest;

	/* now unlock chain */

	while (port != base) {
		ipc_port_t next;

		/* port is in transit */

		assert(ip_active(port));
		assert(port->ip_receiver_name == MACH_PORT_NULL);
		assert(port->ip_destination != IP_NULL);

		next = port->ip_destination;
		ip_unlock(port);
		port = next;
	}

	/* base is not in transit */

	assert(!ip_active(base) ||
	       (base->ip_receiver_name != MACH_PORT_NULL) ||
	       (base->ip_destination == IP_NULL));
	ip_unlock(base);

	return FALSE;
}
Exemplo n.º 19
0
/*
 *	thread_switch:
 *
 *	Context switch.  User may supply thread hint.
 */
kern_return_t
thread_switch(
	struct thread_switch_args *args)
{
	thread_t			thread = THREAD_NULL;
	thread_t			self = current_thread();
	mach_port_name_t		thread_name = args->thread_name;
	int						option = args->option;
	mach_msg_timeout_t		option_time = args->option_time;
	uint32_t				scale_factor = NSEC_PER_MSEC;
	boolean_t				reenable_workq_callback = FALSE;
	boolean_t				depress_option = FALSE;
	boolean_t				wait_option = FALSE;

    /*
     *	Validate and process option.
     */
    switch (option) {

	case SWITCH_OPTION_NONE:
		workqueue_thread_yielded();
		break;
	case SWITCH_OPTION_WAIT:
		wait_option = TRUE;
		workqueue_thread_yielded();
		break;
	case SWITCH_OPTION_DEPRESS:
		depress_option = TRUE;
		workqueue_thread_yielded();
		break;
	case SWITCH_OPTION_DISPATCH_CONTENTION:
		scale_factor = NSEC_PER_USEC;
		wait_option = TRUE;
		if (thread_switch_disable_workqueue_sched_callback())
			reenable_workq_callback = TRUE;
		break;
	case SWITCH_OPTION_OSLOCK_DEPRESS:
		depress_option = TRUE;
		if (thread_switch_disable_workqueue_sched_callback())
			reenable_workq_callback = TRUE;
		break;
	case SWITCH_OPTION_OSLOCK_WAIT:
		wait_option = TRUE;
		if (thread_switch_disable_workqueue_sched_callback())
			reenable_workq_callback = TRUE;
		break;
	default:
	    return (KERN_INVALID_ARGUMENT);
    }

	/*
	 * Translate the port name if supplied.
	 */
	if (thread_name != MACH_PORT_NULL) {
		ipc_port_t port;

		if (ipc_port_translate_send(self->task->itk_space,
		                            thread_name, &port) == KERN_SUCCESS) {
			ip_reference(port);
			ip_unlock(port);

			thread = convert_port_to_thread(port);
			ip_release(port);

			if (thread == self) {
				thread_deallocate(thread);
				thread = THREAD_NULL;
			}
		}
	}

	if (option == SWITCH_OPTION_OSLOCK_DEPRESS || option == SWITCH_OPTION_OSLOCK_WAIT) {
		if (thread != THREAD_NULL) {

			if (thread->task != self->task) {
				/*
				 * OSLock boosting only applies to other threads
				 * in your same task (even if you have a port for
				 * a thread in another task)
				 */

				thread_deallocate(thread);
				thread = THREAD_NULL;
			} else {
				/*
				 * Attempt to kick the lock owner up to our same IO throttling tier.
				 * If the thread is currently blocked in throttle_lowpri_io(),
				 * it will immediately break out.
				 *
				 * TODO: SFI break out?
				 */
				int new_policy = proc_get_effective_thread_policy(self, TASK_POLICY_IO);

				set_thread_iotier_override(thread, new_policy);
			}
		}
	}

	/*
	 * Try to handoff if supplied.
	 */
	if (thread != THREAD_NULL) {
		spl_t s = splsched();

		/* This may return a different thread if the target is pushing on something */
		thread_t pulled_thread = thread_run_queue_remove_for_handoff(thread);

		KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SCHED,MACH_SCHED_THREAD_SWITCH)|DBG_FUNC_NONE,
				      thread_tid(thread), thread->state,
				      pulled_thread ? TRUE : FALSE, 0, 0);

		if (pulled_thread != THREAD_NULL) {
			/* We can't be dropping the last ref here */
			thread_deallocate_safe(thread);

			if (wait_option)
				assert_wait_timeout((event_t)assert_wait_timeout, THREAD_ABORTSAFE,
				                    option_time, scale_factor);
			else if (depress_option)
				thread_depress_ms(option_time);

			self->saved.swtch.option = option;
			self->saved.swtch.reenable_workq_callback = reenable_workq_callback;

			thread_run(self, (thread_continue_t)thread_switch_continue, NULL, pulled_thread);
			/* NOTREACHED */
			panic("returned from thread_run!");
		}

		splx(s);

		thread_deallocate(thread);
	}

	if (wait_option)
		assert_wait_timeout((event_t)assert_wait_timeout, THREAD_ABORTSAFE, option_time, scale_factor);
	else if (depress_option)
		thread_depress_ms(option_time);

	self->saved.swtch.option = option;
	self->saved.swtch.reenable_workq_callback = reenable_workq_callback;

	thread_block_reason((thread_continue_t)thread_switch_continue, NULL, AST_YIELD);

	if (depress_option)
		thread_depress_abort_internal(self);

	if (reenable_workq_callback)
		thread_switch_enable_workqueue_sched_callback();

    return (KERN_SUCCESS);
}
Exemplo n.º 20
0
void
ipc_object_copyout_dest(
	ipc_space_t		space,
	ipc_object_t		object,
	mach_msg_type_name_t	msgt_name,
	mach_port_name_t	*namep)
{
	mach_port_name_t name;

	assert(IO_VALID(object));
	assert(io_active(object));

	io_release(object);

	/*
	 *	If the space is the receiver/owner of the object,
	 *	then we quietly consume the right and return
	 *	the space's name for the object.  Otherwise
	 *	we destroy the right and return MACH_PORT_NULL.
	 */

	switch (msgt_name) {
	    case MACH_MSG_TYPE_PORT_SEND: {
		ipc_port_t port = (ipc_port_t) object;
		ipc_port_t nsrequest = IP_NULL;
		mach_port_mscount_t mscount;

		if (port->ip_receiver == space)
			name = port->ip_receiver_name;
		else
			name = MACH_PORT_NULL;

		assert(port->ip_srights > 0);
		if (--port->ip_srights == 0 &&
		    port->ip_nsrequest != IP_NULL) {
			nsrequest = port->ip_nsrequest;
			port->ip_nsrequest = IP_NULL;
			mscount = port->ip_mscount;
			ip_unlock(port);
			ipc_notify_no_senders(nsrequest, mscount);
		} else
			ip_unlock(port);
		break;
	    }

	    case MACH_MSG_TYPE_PORT_SEND_ONCE: {
		ipc_port_t port = (ipc_port_t) object;

		assert(port->ip_sorights > 0);

		if (port->ip_receiver == space) {
			/* quietly consume the send-once right */

			port->ip_sorights--;
			name = port->ip_receiver_name;
			ip_unlock(port);
		} else {
			/*
			 *	A very bizarre case.  The message
			 *	was received, but before this copyout
			 *	happened the space lost receive rights.
			 *	We can't quietly consume the soright
			 *	out from underneath some other task,
			 *	so generate a send-once notification.
			 */

			ip_reference(port); /* restore ref */
			ip_unlock(port);

			ipc_notify_send_once(port);
			name = MACH_PORT_NULL;
		}

		break;
	    }

	    default:
		panic("ipc_object_copyout_dest: strange rights");
		name = MACH_PORT_DEAD;
	}

	*namep = name;
}
Exemplo n.º 21
0
void
ipc_object_copyin_from_kernel(
	ipc_object_t		object,
	mach_msg_type_name_t	msgt_name)
{
	assert(IO_VALID(object));

	switch (msgt_name) {
	    case MACH_MSG_TYPE_MOVE_RECEIVE: {
		ipc_port_t port = (ipc_port_t) object;

		ip_lock(port);
		assert(ip_active(port));
		if (port->ip_destination != IP_NULL) {
			assert(port->ip_receiver == ipc_space_kernel);

			/* relevant part of ipc_port_clear_receiver */
			ipc_port_set_mscount(port, 0);

			port->ip_receiver_name = MACH_PORT_NULL;
			port->ip_destination = IP_NULL;
		}
		ip_unlock(port);
		break;
	    }

	    case MACH_MSG_TYPE_COPY_SEND: {
		ipc_port_t port = (ipc_port_t) object;

		ip_lock(port);
		if (ip_active(port)) {
			assert(port->ip_srights > 0);
			port->ip_srights++;
		}
		ip_reference(port);
		ip_unlock(port);
		break;
	    }

	    case MACH_MSG_TYPE_MAKE_SEND: {
		ipc_port_t port = (ipc_port_t) object;

		ip_lock(port);
		if (ip_active(port)) {
			assert(port->ip_receiver_name != MACH_PORT_NULL);
			assert((port->ip_receiver == ipc_space_kernel) ||
                   (port->ip_receiver->is_node_id != HOST_LOCAL_NODE));
			port->ip_mscount++;
		}

		port->ip_srights++;
		ip_reference(port);
		ip_unlock(port);
		break;
	    }

	    case MACH_MSG_TYPE_MOVE_SEND: {
		/* move naked send right into the message */
		assert(((ipc_port_t)object)->ip_srights);
		break;
	    }

	    case MACH_MSG_TYPE_MAKE_SEND_ONCE: {
		ipc_port_t port = (ipc_port_t) object;

		ip_lock(port);
		if (ip_active(port)) {
			assert(port->ip_receiver_name != MACH_PORT_NULL);
		}
		port->ip_sorights++;
		ip_reference(port);
		ip_unlock(port);
		break;
	    }

	    case MACH_MSG_TYPE_MOVE_SEND_ONCE: {
		/* move naked send-once right into the message */
	    	assert(((ipc_port_t)object)->ip_sorights);
		break;
	    }

	    default:
		panic("ipc_object_copyin_from_kernel: strange rights");
	}
}
Exemplo n.º 22
0
/*
 *	Routine:	exception_deliver
 *	Purpose:
 *		Make an upcall to the exception server provided.
 *	Conditions:
 *		Nothing locked and no resources held.
 *		Called from an exception context, so
 *		thread_exception_return and thread_kdb_return
 *		are possible.
 *	Returns:
 *		KERN_SUCCESS if the exception was handled
 */
kern_return_t 
exception_deliver(
	thread_t		thread,
	exception_type_t	exception,
	mach_exception_data_t	code,
	mach_msg_type_number_t  codeCnt,
	struct exception_action *excp,
	lck_mtx_t			*mutex)
{
	ipc_port_t		exc_port;
	exception_data_type_t	small_code[EXCEPTION_CODE_MAX];
	int			code64;
	int			behavior;
	int			flavor;
	kern_return_t		kr;

	/*
	 *  Save work if we are terminating.
	 *  Just go back to our AST handler.
	 */
	if (!thread->active)
		return KERN_SUCCESS;

	/*
	 * Snapshot the exception action data under lock for consistency.
	 * Hold a reference to the port over the exception_raise_* calls
	 * so it can't be destroyed.  This seems like overkill, but keeps
	 * the port from disappearing between now and when
	 * ipc_object_copyin_from_kernel is finally called.
	 */
	lck_mtx_lock(mutex);
	exc_port = excp->port;
	if (!IP_VALID(exc_port)) {
		lck_mtx_unlock(mutex);
		return KERN_FAILURE;
	}
	ip_lock(exc_port);
	if (!ip_active(exc_port)) {
		ip_unlock(exc_port);
		lck_mtx_unlock(mutex);
		return KERN_FAILURE;
	}
	ip_reference(exc_port);	
	exc_port->ip_srights++;
	ip_unlock(exc_port);

	flavor = excp->flavor;
	behavior = excp->behavior;
	lck_mtx_unlock(mutex);

	code64 = (behavior & MACH_EXCEPTION_CODES);
	behavior &= ~MACH_EXCEPTION_CODES;

	if (!code64) {
		small_code[0] = CAST_DOWN_EXPLICIT(exception_data_type_t, code[0]);
		small_code[1] = CAST_DOWN_EXPLICIT(exception_data_type_t, code[1]);
	}


	switch (behavior) {
	case EXCEPTION_STATE: {
		mach_msg_type_number_t state_cnt;
		thread_state_data_t state;

		c_thr_exc_raise_state++;
		state_cnt = _MachineStateCount[flavor];
		kr = thread_getstatus(thread, flavor, 
				      (thread_state_t)state,
				      &state_cnt);
		if (kr == KERN_SUCCESS) {
			if (code64) {
				kr = mach_exception_raise_state(exc_port, 
						exception,
						code, 
						codeCnt,
						&flavor,
						state, state_cnt,
						state, &state_cnt);
			} else {
				kr = exception_raise_state(exc_port, exception,
						small_code, 
						codeCnt,
						&flavor,
						state, state_cnt,
						state, &state_cnt);
			}
			if (kr == MACH_MSG_SUCCESS)
				kr = thread_setstatus(thread, flavor, 
						(thread_state_t)state,
						state_cnt);
		}

		return kr;
	}

	case EXCEPTION_DEFAULT:
		c_thr_exc_raise++;
		if (code64) {
			kr = mach_exception_raise(exc_port,
					retrieve_thread_self_fast(thread),
					retrieve_task_self_fast(thread->task),
					exception,
					code, 
					codeCnt);
		} else {
			kr = exception_raise(exc_port,
					retrieve_thread_self_fast(thread),
					retrieve_task_self_fast(thread->task),
					exception,
					small_code, 
					codeCnt);
		}

		return kr;

	case EXCEPTION_STATE_IDENTITY: {
		mach_msg_type_number_t state_cnt;
		thread_state_data_t state;

		c_thr_exc_raise_state_id++;
		state_cnt = _MachineStateCount[flavor];
		kr = thread_getstatus(thread, flavor,
				      (thread_state_t)state,
				      &state_cnt);
		if (kr == KERN_SUCCESS) {
			if (code64) {
				kr = mach_exception_raise_state_identity(
						exc_port,
						retrieve_thread_self_fast(thread),
						retrieve_task_self_fast(thread->task),
						exception,
						code, 
						codeCnt,
						&flavor,
						state, state_cnt,
						state, &state_cnt);
			} else {
				kr = exception_raise_state_identity(exc_port,
						retrieve_thread_self_fast(thread),
						retrieve_task_self_fast(thread->task),
						exception,
						small_code, 
						codeCnt,
						&flavor,
						state, state_cnt,
						state, &state_cnt);
			}
			if (kr == MACH_MSG_SUCCESS)
				kr = thread_setstatus(thread, flavor,
						(thread_state_t)state,
						state_cnt);
		}

		return kr;
	}

	default:
	       panic ("bad exception behavior!");
	       return KERN_FAILURE; 
	}/* switch */
}
Exemplo n.º 23
0
void
exception_raise(
	ipc_port_t 	dest_port,
	ipc_port_t 	thread_port,
	ipc_port_t 	task_port,
	integer_t 	_exception, 
	integer_t 	code, 
	integer_t 	subcode)
{
	ipc_thread_t self = current_thread();
	ipc_thread_t receiver;
	ipc_port_t reply_port;
	ipc_mqueue_t dest_mqueue;
	ipc_mqueue_t reply_mqueue;
	ipc_kmsg_t kmsg;
	mach_msg_return_t mr;

	assert(IP_VALID(dest_port));

	/*
	 *	We will eventually need a message buffer.
	 *	Grab the buffer now, while nothing is locked.
	 *	This buffer will get handed to the exception server,
	 *	and it will give the buffer back with its reply.
	 */

	kmsg = ikm_cache();
	if (kmsg != IKM_NULL) {
		ikm_cache() = IKM_NULL;
		ikm_check_initialized(kmsg, IKM_SAVED_KMSG_SIZE);
	} else {
		kmsg = ikm_alloc(IKM_SAVED_MSG_SIZE);
		if (kmsg == IKM_NULL)
			panic("exception_raise");
		ikm_init(kmsg, IKM_SAVED_MSG_SIZE);
	}

	/*
	 *	We need a reply port for the RPC.
	 *	Check first for a cached port.
	 */

	ith_lock(self);
	assert(self->ith_self != IP_NULL);

	reply_port = self->ith_rpc_reply;
	if (reply_port == IP_NULL) {
		ith_unlock(self);
		reply_port = ipc_port_alloc_reply();
		ith_lock(self);
		if ((reply_port == IP_NULL) ||
		    (self->ith_rpc_reply != IP_NULL))
			panic("exception_raise");
		self->ith_rpc_reply = reply_port;
	}

	ip_lock(reply_port);
	assert(ip_active(reply_port));
	ith_unlock(self);

	/*
	 *	Make a naked send-once right for the reply port,
	 *	to hand to the exception server.
	 *	Make an extra reference for the reply port,
	 *	to receive on.  This protects us against
	 *	mach_msg_abort_rpc.
	 */

	reply_port->ip_sorights++;
	ip_reference(reply_port);

	ip_reference(reply_port);
	self->ith_port = reply_port;

	reply_mqueue = &reply_port->ip_messages;
	imq_lock(reply_mqueue);
	assert(ipc_kmsg_queue_empty(&reply_mqueue->imq_messages));
	ip_unlock(reply_port);

	/*
	 *	Make sure we can queue to the destination port.
	 */

	if (!ip_lock_try(dest_port)) {
		imq_unlock(reply_mqueue);
		goto slow_exception_raise;
	}

	if (!ip_active(dest_port) ||
	    (dest_port->ip_receiver == ipc_space_kernel)) {
		imq_unlock(reply_mqueue);
		ip_unlock(dest_port);
		goto slow_exception_raise;
	}

	/*
	 *	Find the destination message queue.
	 */

    {
	ipc_pset_t dest_pset;

	dest_pset = dest_port->ip_pset;
	if (dest_pset == IPS_NULL)
		dest_mqueue = &dest_port->ip_messages;
	else
		dest_mqueue = &dest_pset->ips_messages;
    }

	if (!imq_lock_try(dest_mqueue)) {
		imq_unlock(reply_mqueue);
		ip_unlock(dest_port);
		goto slow_exception_raise;
	}

	/*
	 *	Safe to unlock dest_port, because we hold
	 *	dest_mqueue locked.  We never bother changing
	 *	dest_port->ip_msgcount.
	 */

	ip_unlock(dest_port);

	receiver = ipc_thread_queue_first(&dest_mqueue->imq_threads);
	if ((receiver == ITH_NULL) ||
	    !((receiver->swap_func == (void (*)()) mach_msg_continue) ||
	      ((receiver->swap_func ==
				(void (*)()) mach_msg_receive_continue) &&
	       (sizeof(struct mach_exception) <= receiver->ith_msize) &&
	       ((receiver->ith_option & MACH_RCV_NOTIFY) == 0))) ||
	    !thread_handoff(self, exception_raise_continue, receiver)) {
		imq_unlock(reply_mqueue);
		imq_unlock(dest_mqueue);
		goto slow_exception_raise;
	}
	counter(c_exception_raise_block++);

	assert(current_thread() == receiver);

	/*
	 *	We need to finish preparing self for its
	 *	time asleep in reply_mqueue.  self is left
	 *	holding the extra ref for reply_port.
	 */

	ipc_thread_enqueue_macro(&reply_mqueue->imq_threads, self);
	self->ith_state = MACH_RCV_IN_PROGRESS;
	self->ith_msize = MACH_MSG_SIZE_MAX;
	imq_unlock(reply_mqueue);

	/*
	 *	Finish extracting receiver from dest_mqueue.
	 */

	ipc_thread_rmqueue_first_macro(
		&dest_mqueue->imq_threads, receiver);
	imq_unlock(dest_mqueue);

	/*
	 *	Release the receiver's reference for his object.
	 */
    {
	ipc_object_t object = receiver->ith_object;

	io_lock(object);
	io_release(object);
	io_check_unlock(object);
    }

    {
	struct mach_exception *exc =
			(struct mach_exception *) &kmsg->ikm_header;
	ipc_space_t space = receiver->task->itk_space;

	/*
	 *	We are running as the receiver now.  We hold
	 *	the following resources, which must be consumed:
	 *		kmsg, send-once right for reply_port
	 *		send rights for dest_port, thread_port, task_port
	 *	Synthesize a kmsg for copyout to the receiver.
	 */

	exc->Head.msgh_bits = (MACH_MSGH_BITS(MACH_MSG_TYPE_PORT_SEND_ONCE,
					      MACH_MSG_TYPE_PORT_SEND) |
			       MACH_MSGH_BITS_COMPLEX);
	exc->Head.msgh_size = sizeof *exc;
     /* exc->Head.msgh_remote_port later */
     /* exc->Head.msgh_local_port later */
	exc->Head.msgh_seqno = 0;
	exc->Head.msgh_id = MACH_EXCEPTION_ID;
	exc->threadType = exc_port_proto;
     /* exc->thread later */
	exc->taskType = exc_port_proto;
     /* exc->task later */
	exc->exceptionType = exc_code_proto;
	exc->exception = _exception;
	exc->codeType = exc_code_proto;
	exc->code = code;
	exc->subcodeType = exc_code_proto;
	exc->subcode = subcode;

	/*
	 *	Check that the receiver can handle the message.
	 */

	if (receiver->ith_rcv_size < sizeof(struct mach_exception)) {
		/*
		 *	ipc_kmsg_destroy is a handy way to consume
		 *	the resources we hold, but it requires setup.
		 */

		exc->Head.msgh_bits =
			(MACH_MSGH_BITS(MACH_MSG_TYPE_PORT_SEND,
					MACH_MSG_TYPE_PORT_SEND_ONCE) |
			 MACH_MSGH_BITS_COMPLEX);
		exc->Head.msgh_remote_port = (mach_port_t) dest_port;
		exc->Head.msgh_local_port = (mach_port_t) reply_port;
		exc->thread = (mach_port_t) thread_port;
		exc->task = (mach_port_t) task_port;

		ipc_kmsg_destroy(kmsg);
		thread_syscall_return(MACH_RCV_TOO_LARGE);
		/*NOTREACHED*/
	}

	is_write_lock(space);
	assert(space->is_active);

	/*
	 *	To do an atomic copyout, need simultaneous
	 *	locks on both ports and the space.
	 */

	ip_lock(dest_port);
	if (!ip_active(dest_port) ||
	    !ip_lock_try(reply_port)) {
	    abort_copyout:
		ip_unlock(dest_port);
		is_write_unlock(space);

		/*
		 *	Oh well, we have to do the header the slow way.
		 *	First make it look like it's in-transit.
		 */

		exc->Head.msgh_bits =
			(MACH_MSGH_BITS(MACH_MSG_TYPE_PORT_SEND,
					MACH_MSG_TYPE_PORT_SEND_ONCE) |
			 MACH_MSGH_BITS_COMPLEX);
		exc->Head.msgh_remote_port = (mach_port_t) dest_port;
		exc->Head.msgh_local_port = (mach_port_t) reply_port;

		mr = ipc_kmsg_copyout_header(&exc->Head, space,
					     MACH_PORT_NULL);
		if (mr == MACH_MSG_SUCCESS)
			goto copyout_body;

		/*
		 *	Ack!  Prepare for ipc_kmsg_copyout_dest.
		 *	It will consume thread_port and task_port.
		 */

		exc->thread = (mach_port_t) thread_port;
		exc->task = (mach_port_t) task_port;

		ipc_kmsg_copyout_dest(kmsg, space);
		(void) ipc_kmsg_put(receiver->ith_msg, kmsg,
				    sizeof(mach_msg_header_t));
		thread_syscall_return(mr);
		/*NOTREACHED*/
	}

	if (!ip_active(reply_port)) {
		ip_unlock(reply_port);
		goto abort_copyout;
	}

	assert(reply_port->ip_sorights > 0);
	ip_unlock(reply_port);

    {
	kern_return_t kr;
	ipc_entry_t entry;

	kr = ipc_entry_get (space, &exc->Head.msgh_remote_port, &entry);
	if (kr)
		goto abort_copyout;
    {
	mach_port_gen_t gen;

	assert((entry->ie_bits &~ IE_BITS_GEN_MASK) == 0);
	gen = entry->ie_bits + IE_BITS_GEN_ONE;

	/* optimized ipc_right_copyout */

	entry->ie_bits = gen | (MACH_PORT_TYPE_SEND_ONCE | 1);
    }

	entry->ie_object = (ipc_object_t) reply_port;
	is_write_unlock(space);
    }

	/* optimized ipc_object_copyout_dest */

	assert(dest_port->ip_srights > 0);
	ip_release(dest_port);

	exc->Head.msgh_local_port =
		((dest_port->ip_receiver == space) ?
		 dest_port->ip_receiver_name : MACH_PORT_NULL);

	if ((--dest_port->ip_srights == 0) &&
	    (dest_port->ip_nsrequest != IP_NULL)) {
		ipc_port_t nsrequest;
		mach_port_mscount_t mscount;

		/* a rather rare case */

		nsrequest = dest_port->ip_nsrequest;
		mscount = dest_port->ip_mscount;
		dest_port->ip_nsrequest = IP_NULL;
		ip_unlock(dest_port);

		ipc_notify_no_senders(nsrequest, mscount);
	} else
		ip_unlock(dest_port);

    copyout_body:
	/*
	 *	Optimized version of ipc_kmsg_copyout_body,
	 *	to handle the two ports in the body.
	 */

	mr = (ipc_kmsg_copyout_object(space, (ipc_object_t) thread_port,
				      MACH_MSG_TYPE_PORT_SEND, &exc->thread) |
	      ipc_kmsg_copyout_object(space, (ipc_object_t) task_port,
				      MACH_MSG_TYPE_PORT_SEND, &exc->task));
	if (mr != MACH_MSG_SUCCESS) {
		(void) ipc_kmsg_put(receiver->ith_msg, kmsg,
				    kmsg->ikm_header.msgh_size);
		thread_syscall_return(mr | MACH_RCV_BODY_ERROR);
		/*NOTREACHED*/
	}
    }

	/*
	 *	Optimized version of ipc_kmsg_put.
	 *	We must check ikm_cache after copyoutmsg.
	 */

	ikm_check_initialized(kmsg, kmsg->ikm_size);
	assert(kmsg->ikm_size == IKM_SAVED_KMSG_SIZE);

	if (copyoutmsg(&kmsg->ikm_header, receiver->ith_msg,
		       sizeof(struct mach_exception)) ||
	    (ikm_cache() != IKM_NULL)) {
		mr = ipc_kmsg_put(receiver->ith_msg, kmsg,
				  kmsg->ikm_header.msgh_size);
		thread_syscall_return(mr);
		/*NOTREACHED*/
	}

	ikm_cache() = kmsg;
	thread_syscall_return(MACH_MSG_SUCCESS);
	/*NOTREACHED*/
#ifndef	__GNUC__
	return; /* help for the compiler */
#endif

    slow_exception_raise: {
	struct mach_exception *exc =
			(struct mach_exception *) &kmsg->ikm_header;
	ipc_kmsg_t reply_kmsg;
	mach_port_seqno_t reply_seqno;

	exception_raise_misses++;

	/*
	 *	We hold the following resources, which must be consumed:
	 *		kmsg, send-once right and ref for reply_port
	 *		send rights for dest_port, thread_port, task_port
	 *	Synthesize a kmsg to send.
	 */

	exc->Head.msgh_bits = (MACH_MSGH_BITS(MACH_MSG_TYPE_PORT_SEND,
					      MACH_MSG_TYPE_PORT_SEND_ONCE) |
			       MACH_MSGH_BITS_COMPLEX);
	exc->Head.msgh_size = sizeof *exc;
	exc->Head.msgh_remote_port = (mach_port_t) dest_port;
	exc->Head.msgh_local_port = (mach_port_t) reply_port;
	exc->Head.msgh_seqno = 0;
	exc->Head.msgh_id = MACH_EXCEPTION_ID;
	exc->threadType = exc_port_proto;
	exc->thread = (mach_port_t) thread_port;
	exc->taskType = exc_port_proto;
	exc->task = (mach_port_t) task_port;
	exc->exceptionType = exc_code_proto;
	exc->exception = _exception;
	exc->codeType = exc_code_proto;
	exc->code = code;
	exc->subcodeType = exc_code_proto;
	exc->subcode = subcode;

	ipc_mqueue_send_always(kmsg);

	/*
	 *	We are left with a ref for reply_port,
	 *	which we use to receive the reply message.
	 */

	ip_lock(reply_port);
	if (!ip_active(reply_port)) {
		ip_unlock(reply_port);
		exception_raise_continue_slow(MACH_RCV_PORT_DIED, IKM_NULL, /*dummy*/0);
		/*NOTREACHED*/
	}

	imq_lock(reply_mqueue);
	ip_unlock(reply_port);

	mr = ipc_mqueue_receive(reply_mqueue, MACH_MSG_OPTION_NONE,
				MACH_MSG_SIZE_MAX,
				MACH_MSG_TIMEOUT_NONE,
				FALSE, exception_raise_continue,
				&reply_kmsg, &reply_seqno);
	/* reply_mqueue is unlocked */

	exception_raise_continue_slow(mr, reply_kmsg, reply_seqno);
	/*NOTREACHED*/
    }
}
Exemplo n.º 24
0
void
ipc_object_copyin_from_kernel(
	ipc_object_t		object,
	mach_msg_type_name_t	msgt_name)
{
	assert(IO_VALID(object));

	switch (msgt_name) {
	    case MACH_MSG_TYPE_MOVE_RECEIVE: {
		ipc_port_t port = (ipc_port_t) object;

		ip_lock(port);
		assert(ip_active(port));
		assert(port->ip_receiver_name != MACH_PORT_NULL);
		assert(port->ip_receiver == ipc_space_kernel);

		/* relevant part of ipc_port_clear_receiver */
		ipc_port_set_mscount(port, 0);

		port->ip_receiver_name = MACH_PORT_NULL;
		port->ip_destination = IP_NULL;
		ipc_port_flag_protected_payload_clear(port);
		ip_unlock(port);
		break;
	    }

	    case MACH_MSG_TYPE_COPY_SEND: {
		ipc_port_t port = (ipc_port_t) object;

		ip_lock(port);
		if (ip_active(port)) {
			assert(port->ip_srights > 0);
			port->ip_srights++;
		}
		ip_reference(port);
		ip_unlock(port);
		break;
	    }

	    case MACH_MSG_TYPE_MAKE_SEND: {
		ipc_port_t port = (ipc_port_t) object;

		ip_lock(port);
		assert(ip_active(port));
		assert(port->ip_receiver_name != MACH_PORT_NULL);
		assert(port->ip_receiver == ipc_space_kernel);

		ip_reference(port);
		port->ip_mscount++;
		port->ip_srights++;
		ip_unlock(port);
		break;
	    }

	    case MACH_MSG_TYPE_MOVE_SEND:
		/* move naked send right into the message */
		break;

	    case MACH_MSG_TYPE_MAKE_SEND_ONCE: {
		ipc_port_t port = (ipc_port_t) object;

		ip_lock(port);
		assert(ip_active(port));
		assert(port->ip_receiver_name != MACH_PORT_NULL);
		assert(port->ip_receiver == ipc_space_kernel);

		ip_reference(port);
		port->ip_sorights++;
		ip_unlock(port);
		break;
	    }

	    case MACH_MSG_TYPE_MOVE_SEND_ONCE:
		/* move naked send-once right into the message */
		break;

	    default:
#if MACH_ASSERT
		assert(!"ipc_object_copyin_from_kernel: strange rights");
#else
		panic("ipc_object_copyin_from_kernel: strange rights");
#endif
	}
}
Exemplo n.º 25
0
kern_return_t
ipc_port_request_grow(
	ipc_port_t		port,
	ipc_table_elems_t 	target_size)
{
	ipc_table_size_t its;
	ipc_port_request_t otable, ntable;

	assert(ip_active(port));

	otable = port->ip_requests;
	if (otable == IPR_NULL)
		its = &ipc_table_requests[0];
	else
		its = otable->ipr_size + 1;

	if (target_size != ITS_SIZE_NONE) {
		if ((otable != IPR_NULL) &&
		    (target_size <= otable->ipr_size->its_size)) {
			ip_unlock(port);
			return KERN_SUCCESS;
	        }
		while ((its->its_size) && (its->its_size < target_size)) {
			its++;
		}
		if (its->its_size == 0) {
			ip_unlock(port);
			return KERN_NO_SPACE;
		}
	}

	ip_reference(port);
	ip_unlock(port);

	if ((its->its_size == 0) ||
	    ((ntable = it_requests_alloc(its)) == IPR_NULL)) {
		ip_release(port);
		return KERN_RESOURCE_SHORTAGE;
	}

	ip_lock(port);

	/*
	 *	Check that port is still active and that nobody else
	 *	has slipped in and grown the table on us.  Note that
	 *	just checking if the current table pointer == otable
	 *	isn't sufficient; must check ipr_size.
	 */

	if (ip_active(port) && (port->ip_requests == otable) &&
	    ((otable == IPR_NULL) || (otable->ipr_size+1 == its))) {
		ipc_table_size_t oits;
		ipc_table_elems_t osize, nsize;
		ipc_port_request_index_t free, i;

		/* copy old table to new table */

		if (otable != IPR_NULL) {
			oits = otable->ipr_size;
			osize = oits->its_size;
			free = otable->ipr_next;

			(void) memcpy((void *)(ntable + 1),
			      (const void *)(otable + 1),
			      (osize - 1) * sizeof(struct ipc_port_request));
		} else {
			osize = 1;
			oits = 0;
			free = 0;
		}

		nsize = its->its_size;
		assert(nsize > osize);

		/* add new elements to the new table's free list */

		for (i = osize; i < nsize; i++) {
			ipc_port_request_t ipr = &ntable[i];

			ipr->ipr_name = MACH_PORT_NULL;
			ipr->ipr_next = free;
			free = i;
		}

		ntable->ipr_next = free;
		ntable->ipr_size = its;
		port->ip_requests = ntable;
		ip_unlock(port);
		ip_release(port);

		if (otable != IPR_NULL) {
			it_requests_free(oits, otable);
	        }
	} else {
		ip_unlock(port);
		ip_release(port);
		it_requests_free(its, ntable);
	}

	return KERN_SUCCESS;
}
Exemplo n.º 26
0
mach_msg_return_t
mach_msg_trap(
	mach_msg_header_t 	*msg,
	mach_msg_option_t 	option,
	mach_msg_size_t 	send_size,
	mach_msg_size_t 	rcv_size,
	mach_port_t 		rcv_name,
	mach_msg_timeout_t 	time_out,
	mach_port_t 		notify)
{
	mach_msg_return_t mr;

	/* first check for common cases */

	if (option == (MACH_SEND_MSG|MACH_RCV_MSG)) {
		ipc_thread_t self = current_thread();
		ipc_space_t space = self->task->itk_space;
		ipc_kmsg_t kmsg;
		ipc_port_t dest_port;
		ipc_object_t rcv_object;
		ipc_mqueue_t rcv_mqueue;
		mach_msg_size_t reply_size;

		/*
		 *	This case is divided into ten sections, each
		 *	with a label.  There are five optimized
		 *	sections and six unoptimized sections, which
		 *	do the same thing but handle all possible
		 *	cases and are slower.
		 *
		 *	The five sections for an RPC are
		 *	    1) Get request message into a buffer.
		 *		(fast_get or slow_get)
		 *	    2) Copyin request message and rcv_name.
		 *		(fast_copyin or slow_copyin)
		 *	    3) Enqueue request and dequeue reply.
		 *		(fast_send_receive or
		 *		 slow_send and slow_receive)
		 *	    4) Copyout reply message.
		 *		(fast_copyout or slow_copyout)
		 *	    5) Put reply message to user's buffer.
		 *		(fast_put or slow_put)
		 *
		 *	Keep the locking hierarchy firmly in mind.
		 *	(First spaces, then ports, then port sets,
		 *	then message queues.)  Only a non-blocking
		 *	attempt can be made to acquire locks out of
		 *	order, or acquire two locks on the same level.
		 *	Acquiring two locks on the same level will
		 *	fail if the objects are really the same,
		 *	unless simple locking is disabled.  This is OK,
		 *	because then the extra unlock does nothing.
		 *
		 *	There are two major reasons these RPCs can't use
		 *	ipc_thread_switch, and use slow_send/slow_receive:
		 *		1) Kernel RPCs.
		 *		2) Servers fall behind clients, so
		 *		client doesn't find a blocked server thread and
		 *		server finds waiting messages and can't block.
		 */

	/*
	    fast_get:
	*/
		/*
		 *	optimized ipc_kmsg_get
		 *
		 *	No locks, references, or messages held.
		 *	We must clear ikm_cache before copyinmsg.
		 */

		if ((send_size > IKM_SAVED_MSG_SIZE) ||
		    (send_size < sizeof(mach_msg_header_t)) ||
		    (send_size & 3) ||
		    ((kmsg = ikm_cache()) == IKM_NULL))
			goto slow_get;

		ikm_cache() = IKM_NULL;
		ikm_check_initialized(kmsg, IKM_SAVED_KMSG_SIZE);

		if (copyinmsg(msg, &kmsg->ikm_header,
			      send_size)) {
			ikm_free(kmsg);
			goto slow_get;
		}

		kmsg->ikm_header.msgh_size = send_size;

	    fast_copyin:
		/*
		 *	optimized ipc_kmsg_copyin/ipc_mqueue_copyin
		 *
		 *	We have the request message data in kmsg.
		 *	Must still do copyin, send, receive, etc.
		 *
		 *	If the message isn't simple, we can't combine
		 *	ipc_kmsg_copyin_header and ipc_mqueue_copyin,
		 *	because copyin of the message body might
		 *	affect rcv_name.
		 */

		switch (kmsg->ikm_header.msgh_bits) {
		    case MACH_MSGH_BITS(MACH_MSG_TYPE_COPY_SEND,
					MACH_MSG_TYPE_MAKE_SEND_ONCE): {
			ipc_entry_t table;
			ipc_entry_num_t size;
			ipc_port_t reply_port;

			/* sending a request message */

		    {
			mach_port_index_t index;
			mach_port_gen_t gen;

		    {
			mach_port_t reply_name =
				kmsg->ikm_header.msgh_local_port;

			if (reply_name != rcv_name)
				goto slow_copyin;

			/* optimized ipc_entry_lookup of reply_name */

			index = MACH_PORT_INDEX(reply_name);
			gen = MACH_PORT_GEN(reply_name);
		    }

			is_read_lock(space);
			assert(space->is_active);

			size = space->is_table_size;
			table = space->is_table;

			if (index >= size)
				goto abort_request_copyin;

		    {
			ipc_entry_t entry;
			ipc_entry_bits_t bits;

			entry = &table[index];
			bits = entry->ie_bits;

			/* check generation number and type bit */

			if ((bits & (IE_BITS_GEN_MASK|
				     MACH_PORT_TYPE_RECEIVE)) !=
			    (gen | MACH_PORT_TYPE_RECEIVE))
				goto abort_request_copyin;

			reply_port = (ipc_port_t) entry->ie_object;
			assert(reply_port != IP_NULL);
		    }
		    }

			/* optimized ipc_entry_lookup of dest_name */

		    {
			mach_port_index_t index;
			mach_port_gen_t gen;

		    {
			mach_port_t dest_name =
				kmsg->ikm_header.msgh_remote_port;

			index = MACH_PORT_INDEX(dest_name);
			gen = MACH_PORT_GEN(dest_name);
		    }

			if (index >= size)
				goto abort_request_copyin;

		    {
			ipc_entry_t entry;
			ipc_entry_bits_t bits;

			entry = &table[index];
			bits = entry->ie_bits;

			/* check generation number and type bit */

			if ((bits & (IE_BITS_GEN_MASK|MACH_PORT_TYPE_SEND)) !=
			    (gen | MACH_PORT_TYPE_SEND))
				goto abort_request_copyin;

			assert(IE_BITS_UREFS(bits) > 0);

			dest_port = (ipc_port_t) entry->ie_object;
			assert(dest_port != IP_NULL);
		    }
		    }

			/*
			 *	To do an atomic copyin, need simultaneous
			 *	locks on both ports and the space.  If
			 *	dest_port == reply_port, and simple locking is
			 *	enabled, then we will abort.  Otherwise it's
			 *	OK to unlock twice.
			 */

			ip_lock(dest_port);
			if (!ip_active(dest_port) ||
			    !ip_lock_try(reply_port)) {
				ip_unlock(dest_port);
				goto abort_request_copyin;
			}
			is_read_unlock(space);

			assert(dest_port->ip_srights > 0);
			dest_port->ip_srights++;
			ip_reference(dest_port);

			assert(ip_active(reply_port));
			assert(reply_port->ip_receiver_name ==
			       kmsg->ikm_header.msgh_local_port);
			assert(reply_port->ip_receiver == space);

			reply_port->ip_sorights++;
			ip_reference(reply_port);

			kmsg->ikm_header.msgh_bits =
				MACH_MSGH_BITS(MACH_MSG_TYPE_PORT_SEND,
					       MACH_MSG_TYPE_PORT_SEND_ONCE);
			kmsg->ikm_header.msgh_remote_port =
					(mach_port_t) dest_port;
			kmsg->ikm_header.msgh_local_port =
					(mach_port_t) reply_port;

			/* make sure we can queue to the destination */

			if (dest_port->ip_receiver == ipc_space_kernel) {
				/*
				 * The kernel server has a reference to
				 * the reply port, which it hands back
				 * to us in the reply message.  We do
				 * not need to keep another reference to
				 * it.
				 */
				ip_unlock(reply_port);

				assert(ip_active(dest_port));
				ip_unlock(dest_port);
				goto kernel_send;
			}

			if (dest_port->ip_msgcount >= dest_port->ip_qlimit)
				goto abort_request_send_receive;

			/* optimized ipc_mqueue_copyin */

			if (reply_port->ip_pset != IPS_NULL)
				goto abort_request_send_receive;

			rcv_object = (ipc_object_t) reply_port;
			io_reference(rcv_object);
			rcv_mqueue = &reply_port->ip_messages;
			imq_lock(rcv_mqueue);
			io_unlock(rcv_object);
			goto fast_send_receive;

		    abort_request_copyin:
			is_read_unlock(space);
			goto slow_copyin;

		    abort_request_send_receive:
			ip_unlock(dest_port);
			ip_unlock(reply_port);
			goto slow_send;
		    }

		    case MACH_MSGH_BITS(MACH_MSG_TYPE_MOVE_SEND_ONCE, 0): {
			ipc_entry_num_t size;
			ipc_entry_t table;

			/* sending a reply message */

		    {
			mach_port_t reply_name =
				kmsg->ikm_header.msgh_local_port;

			if (reply_name != MACH_PORT_NULL)
				goto slow_copyin;
		    }

			is_write_lock(space);
			assert(space->is_active);

			/* optimized ipc_entry_lookup */

			size = space->is_table_size;
			table = space->is_table;

		    {
			ipc_entry_t entry;
			mach_port_gen_t gen;
			mach_port_index_t index;

		    {
			mach_port_t dest_name =
				kmsg->ikm_header.msgh_remote_port;

			index = MACH_PORT_INDEX(dest_name);
			gen = MACH_PORT_GEN(dest_name);
		    }

			if (index >= size)
				goto abort_reply_dest_copyin;

			entry = &table[index];

			/* check generation, collision bit, and type bit */

			if ((entry->ie_bits & (IE_BITS_GEN_MASK|
					       IE_BITS_COLLISION|
					       MACH_PORT_TYPE_SEND_ONCE)) !=
			    (gen | MACH_PORT_TYPE_SEND_ONCE))
				goto abort_reply_dest_copyin;

			/* optimized ipc_right_copyin */

			assert(IE_BITS_TYPE(entry->ie_bits) ==
						MACH_PORT_TYPE_SEND_ONCE);
			assert(IE_BITS_UREFS(entry->ie_bits) == 1);
			assert((entry->ie_bits & IE_BITS_MAREQUEST) == 0);

			if (entry->ie_request != 0)
				goto abort_reply_dest_copyin;

			dest_port = (ipc_port_t) entry->ie_object;
			assert(dest_port != IP_NULL);

			ip_lock(dest_port);
			if (!ip_active(dest_port)) {
				ip_unlock(dest_port);
				goto abort_reply_dest_copyin;
			}

			assert(dest_port->ip_sorights > 0);

			/* optimized ipc_entry_dealloc */

			entry->ie_next = table->ie_next;
			table->ie_next = index;
			entry->ie_bits = gen;
			entry->ie_object = IO_NULL;
		    }

			kmsg->ikm_header.msgh_bits =
				MACH_MSGH_BITS(MACH_MSG_TYPE_PORT_SEND_ONCE,
					       0);
			kmsg->ikm_header.msgh_remote_port =
					(mach_port_t) dest_port;

			/* make sure we can queue to the destination */

			assert(dest_port->ip_receiver != ipc_space_kernel);

			/* optimized ipc_entry_lookup/ipc_mqueue_copyin */

		    {
			ipc_entry_t entry;
			ipc_entry_bits_t bits;

		    {
			mach_port_index_t index;
			mach_port_gen_t gen;

			index = MACH_PORT_INDEX(rcv_name);
			gen = MACH_PORT_GEN(rcv_name);

			if (index >= size)
				goto abort_reply_rcv_copyin;

			entry = &table[index];
			bits = entry->ie_bits;

			/* check generation number */

			if ((bits & IE_BITS_GEN_MASK) != gen)
				goto abort_reply_rcv_copyin;
		    }

			/* check type bits; looking for receive or set */

			if (bits & MACH_PORT_TYPE_PORT_SET) {
				ipc_pset_t rcv_pset;

				rcv_pset = (ipc_pset_t) entry->ie_object;
				assert(rcv_pset != IPS_NULL);

				ips_lock(rcv_pset);
				assert(ips_active(rcv_pset));

				rcv_object = (ipc_object_t) rcv_pset;
				rcv_mqueue = &rcv_pset->ips_messages;
			} else if (bits & MACH_PORT_TYPE_RECEIVE) {
				ipc_port_t rcv_port;

				rcv_port = (ipc_port_t) entry->ie_object;
				assert(rcv_port != IP_NULL);

				if (!ip_lock_try(rcv_port))
					goto abort_reply_rcv_copyin;
				assert(ip_active(rcv_port));

				if (rcv_port->ip_pset != IPS_NULL) {
					ip_unlock(rcv_port);
					goto abort_reply_rcv_copyin;
				}

				rcv_object = (ipc_object_t) rcv_port;
				rcv_mqueue = &rcv_port->ip_messages;
			} else
				goto abort_reply_rcv_copyin;
		    }

			is_write_unlock(space);
			io_reference(rcv_object);
			imq_lock(rcv_mqueue);
			io_unlock(rcv_object);
			goto fast_send_receive;

		    abort_reply_dest_copyin:
			is_write_unlock(space);
			goto slow_copyin;

		    abort_reply_rcv_copyin:
			ip_unlock(dest_port);
			is_write_unlock(space);
			goto slow_send;
		    }

		    default:
			goto slow_copyin;
		}
		/*NOTREACHED*/

	    fast_send_receive:
		/*
		 *	optimized ipc_mqueue_send/ipc_mqueue_receive
		 *
		 *	Finished get/copyin of kmsg and copyin of rcv_name.
		 *	space is unlocked, dest_port is locked,
		 *	we can queue kmsg to dest_port,
		 *	rcv_mqueue is locked, rcv_object holds a ref,
		 *	if rcv_object is a port it isn't in a port set
		 *
		 *	Note that if simple locking is turned off,
		 *	then we could have dest_mqueue == rcv_mqueue
		 *	and not abort when we try to lock dest_mqueue.
		 */

		assert(ip_active(dest_port));
		assert(dest_port->ip_receiver != ipc_space_kernel);
		assert((dest_port->ip_msgcount < dest_port->ip_qlimit) ||
		       (MACH_MSGH_BITS_REMOTE(kmsg->ikm_header.msgh_bits) ==
						MACH_MSG_TYPE_PORT_SEND_ONCE));
		assert((kmsg->ikm_header.msgh_bits &
						MACH_MSGH_BITS_CIRCULAR) == 0);

	    {
		ipc_mqueue_t dest_mqueue;
		ipc_thread_t receiver;

	    {
		ipc_pset_t dest_pset;

		dest_pset = dest_port->ip_pset;
		if (dest_pset == IPS_NULL)
			dest_mqueue = &dest_port->ip_messages;
		else
			dest_mqueue = &dest_pset->ips_messages;
	    }

		if (!imq_lock_try(dest_mqueue)) {
		    abort_send_receive:
			ip_unlock(dest_port);
			imq_unlock(rcv_mqueue);
			ipc_object_release(rcv_object);
			goto slow_send;
		}

		receiver = ipc_thread_queue_first(&dest_mqueue->imq_threads);
		if ((receiver == ITH_NULL) ||
		    (ipc_kmsg_queue_first(&rcv_mqueue->imq_messages)
								!= IKM_NULL)) {
			imq_unlock(dest_mqueue);
			goto abort_send_receive;
		}

		/*
		 *	There is a receiver thread waiting, and
		 *	there is no reply message for us to pick up.
		 *	We have hope of hand-off, so save state.
		 */

		self->ith_msg = msg;
		self->ith_rcv_size = rcv_size;
		self->ith_object = rcv_object;
		self->ith_mqueue = rcv_mqueue;

		if ((receiver->swap_func == (void (*)()) mach_msg_continue) &&
		    thread_handoff(self, mach_msg_continue, receiver)) {
			assert(current_thread() == receiver);

			/*
			 *	We can use the optimized receive code,
			 *	because the receiver is using no options.
			 */
		} else if ((receiver->swap_func ==
				(void (*)()) exception_raise_continue) &&
			   thread_handoff(self, mach_msg_continue, receiver)) {
			counter(c_mach_msg_trap_block_exc++);
			assert(current_thread() == receiver);

			/*
			 *	We are a reply message coming back through
			 *	the optimized exception-handling path.
			 *	Finish with rcv_mqueue and dest_mqueue,
			 *	and then jump to exception code with
			 *	dest_port still locked.  We don't bother
			 *	with a sequence number in this case.
			 */

			ipc_thread_enqueue_macro(
				&rcv_mqueue->imq_threads, self);
			self->ith_state = MACH_RCV_IN_PROGRESS;
			self->ith_msize = MACH_MSG_SIZE_MAX;
			imq_unlock(rcv_mqueue);

			ipc_thread_rmqueue_first_macro(
				&dest_mqueue->imq_threads, receiver);
			imq_unlock(dest_mqueue);

			exception_raise_continue_fast(dest_port, kmsg);
			/*NOTREACHED*/
			return MACH_MSG_SUCCESS;
		} else if ((send_size <= receiver->ith_msize) &&
			   thread_handoff(self, mach_msg_continue, receiver)) {
			assert(current_thread() == receiver);

			if ((receiver->swap_func ==
				(void (*)()) mach_msg_receive_continue) &&
			    ((receiver->ith_option & MACH_RCV_NOTIFY) == 0)) {
				/*
				 *	We can still use the optimized code.
				 */
			} else {
				counter(c_mach_msg_trap_block_slow++);
				/*
				 *	We are running as the receiver,
				 *	but we can't use the optimized code.
				 *	Finish send/receive processing.
				 */

				dest_port->ip_msgcount++;
				ip_unlock(dest_port);

				ipc_thread_enqueue_macro(
					&rcv_mqueue->imq_threads, self);
				self->ith_state = MACH_RCV_IN_PROGRESS;
				self->ith_msize = MACH_MSG_SIZE_MAX;
				imq_unlock(rcv_mqueue);

				ipc_thread_rmqueue_first_macro(
					&dest_mqueue->imq_threads, receiver);
				receiver->ith_state = MACH_MSG_SUCCESS;
				receiver->ith_kmsg = kmsg;
				receiver->ith_seqno = dest_port->ip_seqno++;
				imq_unlock(dest_mqueue);

				/*
				 *	Call the receiver's continuation.
				 */

				receiver->wait_result = THREAD_AWAKENED;
				(*receiver->swap_func)();
				/*NOTREACHED*/
				return MACH_MSG_SUCCESS;
			}
		} else {
			/*
			 *	The receiver can't accept the message,
			 *	or we can't switch to the receiver.
			 */

			imq_unlock(dest_mqueue);
			goto abort_send_receive;
		}
		counter(c_mach_msg_trap_block_fast++);

		/*
		 *	Safe to unlock dest_port now that we are
		 *	committed to this path, because we hold
		 *	dest_mqueue locked.  We never bother changing
		 *	dest_port->ip_msgcount.
		 */

		ip_unlock(dest_port);

		/*
		 *	We need to finish preparing self for its
		 *	time asleep in rcv_mqueue.
		 */

		ipc_thread_enqueue_macro(&rcv_mqueue->imq_threads, self);
		self->ith_state = MACH_RCV_IN_PROGRESS;
		self->ith_msize = MACH_MSG_SIZE_MAX;
		imq_unlock(rcv_mqueue);

		/*
		 *	Finish extracting receiver from dest_mqueue.
		 */

		ipc_thread_rmqueue_first_macro(
			&dest_mqueue->imq_threads, receiver);
		kmsg->ikm_header.msgh_seqno = dest_port->ip_seqno++;
		imq_unlock(dest_mqueue);

		/*
		 *	We don't have to do any post-dequeue processing of
		 *	the message.  We never incremented ip_msgcount, we
		 *	know it has no msg-accepted request, and blocked
		 *	senders aren't a worry because we found the port
		 *	with a receiver waiting.
		 */

		self = receiver;
		space = self->task->itk_space;

		msg = self->ith_msg;
		rcv_size = self->ith_rcv_size;
		rcv_object = self->ith_object;

		/* inline ipc_object_release */
		io_lock(rcv_object);
		io_release(rcv_object);
		io_check_unlock(rcv_object);
	    }

	    fast_copyout:
		/*
		 *	Nothing locked and no references held, except
		 *	we have kmsg with msgh_seqno filled in.  Must
		 *	still check against rcv_size and do
		 *	ipc_kmsg_copyout/ipc_kmsg_put.
		 */

		assert((ipc_port_t) kmsg->ikm_header.msgh_remote_port
						== dest_port);

		reply_size = kmsg->ikm_header.msgh_size;
		if (rcv_size < reply_size)
			goto slow_copyout;

		/* optimized ipc_kmsg_copyout/ipc_kmsg_copyout_header */

		switch (kmsg->ikm_header.msgh_bits) {
		    case MACH_MSGH_BITS(MACH_MSG_TYPE_PORT_SEND,
					MACH_MSG_TYPE_PORT_SEND_ONCE): {
			ipc_port_t reply_port =
				(ipc_port_t) kmsg->ikm_header.msgh_local_port;
			mach_port_t dest_name, reply_name;

			/* receiving a request message */

			if (!IP_VALID(reply_port))
				goto slow_copyout;

			is_write_lock(space);
			assert(space->is_active);

			/*
			 *	To do an atomic copyout, need simultaneous
			 *	locks on both ports and the space.  If
			 *	dest_port == reply_port, and simple locking is
			 *	enabled, then we will abort.  Otherwise it's
			 *	OK to unlock twice.
			 */

			ip_lock(dest_port);
			if (!ip_active(dest_port) ||
			    !ip_lock_try(reply_port))
				goto abort_request_copyout;

			if (!ip_active(reply_port)) {
				ip_unlock(reply_port);
				goto abort_request_copyout;
			}

			assert(reply_port->ip_sorights > 0);
			ip_unlock(reply_port);

		    {
			ipc_entry_t table;
			ipc_entry_t entry;
			mach_port_index_t index;

			/* optimized ipc_entry_get */

			table = space->is_table;
			index = table->ie_next;

			if (index == 0)
				goto abort_request_copyout;

			entry = &table[index];
			table->ie_next = entry->ie_next;
			entry->ie_request = 0;

		    {
			mach_port_gen_t gen;

			assert((entry->ie_bits &~ IE_BITS_GEN_MASK) == 0);
			gen = entry->ie_bits + IE_BITS_GEN_ONE;

			reply_name = MACH_PORT_MAKE(index, gen);

			/* optimized ipc_right_copyout */

			entry->ie_bits = gen | (MACH_PORT_TYPE_SEND_ONCE | 1);
		    }

			assert(MACH_PORT_VALID(reply_name));
			entry->ie_object = (ipc_object_t) reply_port;
			is_write_unlock(space);
		    }

			/* optimized ipc_object_copyout_dest */

			assert(dest_port->ip_srights > 0);
			ip_release(dest_port);

			if (dest_port->ip_receiver == space)
				dest_name = dest_port->ip_receiver_name;
			else
				dest_name = MACH_PORT_NULL;

			if ((--dest_port->ip_srights == 0) &&
			    (dest_port->ip_nsrequest != IP_NULL)) {
				ipc_port_t nsrequest;
				mach_port_mscount_t mscount;

				/* a rather rare case */

				nsrequest = dest_port->ip_nsrequest;
				mscount = dest_port->ip_mscount;
				dest_port->ip_nsrequest = IP_NULL;
				ip_unlock(dest_port);

				ipc_notify_no_senders(nsrequest, mscount);
			} else
				ip_unlock(dest_port);

			if (! ipc_port_flag_protected_payload(dest_port)) {
				kmsg->ikm_header.msgh_bits = MACH_MSGH_BITS(
					MACH_MSG_TYPE_PORT_SEND_ONCE,
					MACH_MSG_TYPE_PORT_SEND);
				kmsg->ikm_header.msgh_local_port = dest_name;
			} else {
				kmsg->ikm_header.msgh_bits = MACH_MSGH_BITS(
					MACH_MSG_TYPE_PORT_SEND_ONCE,
					MACH_MSG_TYPE_PROTECTED_PAYLOAD);
				kmsg->ikm_header.msgh_protected_payload =
					dest_port->ip_protected_payload;
			}
			kmsg->ikm_header.msgh_remote_port = reply_name;
			goto fast_put;

		    abort_request_copyout:
			ip_unlock(dest_port);
			is_write_unlock(space);
			goto slow_copyout;
		    }

		    case MACH_MSGH_BITS(MACH_MSG_TYPE_PORT_SEND_ONCE, 0): {
			mach_port_t dest_name;

			/* receiving a reply message */

			ip_lock(dest_port);
			if (!ip_active(dest_port))
				goto slow_copyout;

			/* optimized ipc_object_copyout_dest */

			assert(dest_port->ip_sorights > 0);

			if (dest_port->ip_receiver == space) {
				ip_release(dest_port);
				dest_port->ip_sorights--;
				dest_name = dest_port->ip_receiver_name;
				ip_unlock(dest_port);
			} else {
				ip_unlock(dest_port);

				ipc_notify_send_once(dest_port);
				dest_name = MACH_PORT_NULL;
			}

			if (! ipc_port_flag_protected_payload(dest_port)) {
				kmsg->ikm_header.msgh_bits = MACH_MSGH_BITS(
					0,
					MACH_MSG_TYPE_PORT_SEND_ONCE);
				kmsg->ikm_header.msgh_local_port = dest_name;
			} else {
				kmsg->ikm_header.msgh_bits = MACH_MSGH_BITS(
					0,
					MACH_MSG_TYPE_PROTECTED_PAYLOAD);
				kmsg->ikm_header.msgh_protected_payload =
					dest_port->ip_protected_payload;
			}
			kmsg->ikm_header.msgh_remote_port = MACH_PORT_NULL;
			goto fast_put;
		    }

		    case MACH_MSGH_BITS_COMPLEX|
			 MACH_MSGH_BITS(MACH_MSG_TYPE_PORT_SEND_ONCE, 0): {
			mach_port_t dest_name;

			/* receiving a complex reply message */

			ip_lock(dest_port);
			if (!ip_active(dest_port))
				goto slow_copyout;

			/* optimized ipc_object_copyout_dest */

			assert(dest_port->ip_sorights > 0);

			if (dest_port->ip_receiver == space) {
				ip_release(dest_port);
				dest_port->ip_sorights--;
				dest_name = dest_port->ip_receiver_name;
				ip_unlock(dest_port);
			} else {
				ip_unlock(dest_port);

				ipc_notify_send_once(dest_port);
				dest_name = MACH_PORT_NULL;
			}

			if (! ipc_port_flag_protected_payload(dest_port)) {
				kmsg->ikm_header.msgh_bits =
					MACH_MSGH_BITS_COMPLEX
					| MACH_MSGH_BITS(
						0,
						MACH_MSG_TYPE_PORT_SEND_ONCE);
				kmsg->ikm_header.msgh_local_port = dest_name;
			} else {
				kmsg->ikm_header.msgh_bits =
					MACH_MSGH_BITS_COMPLEX
					| MACH_MSGH_BITS(
					    0,
					    MACH_MSG_TYPE_PROTECTED_PAYLOAD);
				kmsg->ikm_header.msgh_protected_payload =
					dest_port->ip_protected_payload;
			}
			kmsg->ikm_header.msgh_remote_port = MACH_PORT_NULL;

			mr = ipc_kmsg_copyout_body(
				(vm_offset_t) (&kmsg->ikm_header + 1),
				(vm_offset_t) &kmsg->ikm_header
					+ kmsg->ikm_header.msgh_size,
				space,
				current_map());

			if (mr != MACH_MSG_SUCCESS) {
				(void) ipc_kmsg_put(msg, kmsg,
					kmsg->ikm_header.msgh_size);
				return mr | MACH_RCV_BODY_ERROR;
			}
			goto fast_put;
		    }

		    default:
			goto slow_copyout;
		}
		/*NOTREACHED*/

	    fast_put:
		/*
		 *	We have the reply message data in kmsg,
		 *	and the reply message size in reply_size.
		 *	Just need to copy it out to the user and free kmsg.
		 *	We must check ikm_cache after copyoutmsg.
		 */

		ikm_check_initialized(kmsg, kmsg->ikm_size);

		if ((kmsg->ikm_size != IKM_SAVED_KMSG_SIZE) ||
		    copyoutmsg(&kmsg->ikm_header, msg,
			       reply_size) ||
		    (ikm_cache() != IKM_NULL))
			goto slow_put;

		ikm_cache() = kmsg;
		thread_syscall_return(MACH_MSG_SUCCESS);
		/*NOTREACHED*/
		return MACH_MSG_SUCCESS; /* help for the compiler */

		/*
		 *	The slow path has a few non-register temporary
		 *	variables used only for call-by-reference.
		 */

	    {
		ipc_kmsg_t temp_kmsg;
		mach_port_seqno_t temp_seqno;
		ipc_object_t temp_rcv_object;
		ipc_mqueue_t temp_rcv_mqueue;

	    slow_get:
		/*
		 *	No locks, references, or messages held.
		 *	Still have to get the request, send it,
		 *	receive reply, etc.
		 */

		mr = ipc_kmsg_get(msg, send_size, &temp_kmsg);
		if (mr != MACH_MSG_SUCCESS) {
			thread_syscall_return(mr);
			/*NOTREACHED*/
		}
		kmsg = temp_kmsg;

		/* try to get back on optimized path */
		goto fast_copyin;

	    slow_copyin:
		/*
		 *	We have the message data in kmsg, but
		 *	we still need to copyin, send it,
		 *	receive a reply, and do copyout.
		 */

		mr = ipc_kmsg_copyin(kmsg, space, current_map(),
				     MACH_PORT_NULL);
		if (mr != MACH_MSG_SUCCESS) {
			ikm_free(kmsg);
			thread_syscall_return(mr);
			/*NOTREACHED*/
		}

		/* try to get back on optimized path */

		if (kmsg->ikm_header.msgh_bits & MACH_MSGH_BITS_CIRCULAR)
			goto slow_send;

		dest_port = (ipc_port_t) kmsg->ikm_header.msgh_remote_port;
		assert(IP_VALID(dest_port));

		ip_lock(dest_port);
		if (dest_port->ip_receiver == ipc_space_kernel) {
			assert(ip_active(dest_port));
			ip_unlock(dest_port);
			goto kernel_send;
		}

		if (ip_active(dest_port) &&
		    ((dest_port->ip_msgcount < dest_port->ip_qlimit) ||
		     (MACH_MSGH_BITS_REMOTE(kmsg->ikm_header.msgh_bits) ==
					MACH_MSG_TYPE_PORT_SEND_ONCE)))
		{
		    /*
		     *	Try an optimized ipc_mqueue_copyin.
		     *	It will work if this is a request message.
		     */

		    ipc_port_t reply_port;

		    reply_port = (ipc_port_t)
					kmsg->ikm_header.msgh_local_port;
		    if (IP_VALID(reply_port)) {
			if (ip_lock_try(reply_port)) {
			    if (ip_active(reply_port) &&
				reply_port->ip_receiver == space &&
				reply_port->ip_receiver_name == rcv_name &&
				reply_port->ip_pset == IPS_NULL)
			    {
				/* Grab a reference to the reply port. */
				rcv_object = (ipc_object_t) reply_port;
				io_reference(rcv_object);
				rcv_mqueue = &reply_port->ip_messages;
				imq_lock(rcv_mqueue);
				io_unlock(rcv_object);
				goto fast_send_receive;
			    }
			    ip_unlock(reply_port);
			}
		    }
		}

		ip_unlock(dest_port);
		goto slow_send;

	    kernel_send:
		/*
		 *	Special case: send message to kernel services.
		 *	The request message has been copied into the
		 *	kmsg.  Nothing is locked.
		 */

	    {
		ipc_port_t	reply_port;

		/*
		 * Perform the kernel function.
		 */

		kmsg = ipc_kobject_server(kmsg);
		if (kmsg == IKM_NULL) {
			/*
			 * No reply.  Take the
			 * slow receive path.
			 */
			goto slow_get_rcv_port;
		}

		/*
		 * Check that:
		 *	the reply port is alive
		 *	we hold the receive right
		 *	the name has not changed.
		 *	the port is not in a set
		 * If any of these are not true,
		 * we cannot directly receive the reply
		 * message.
		 */
		reply_port = (ipc_port_t) kmsg->ikm_header.msgh_remote_port;
		ip_lock(reply_port);

		if ((!ip_active(reply_port)) ||
		    (reply_port->ip_receiver != space) ||
		    (reply_port->ip_receiver_name != rcv_name) ||
		    (reply_port->ip_pset != IPS_NULL))
		{
			ip_unlock(reply_port);
			ipc_mqueue_send_always(kmsg);
			goto slow_get_rcv_port;
		}

		rcv_mqueue = &reply_port->ip_messages;
		imq_lock(rcv_mqueue);
		/* keep port locked, and don`t change ref count yet */

		/*
		 * If there are messages on the port
		 * or other threads waiting for a message,
		 * we cannot directly receive the reply.
		 */
		if ((ipc_thread_queue_first(&rcv_mqueue->imq_threads)
			!= ITH_NULL) ||
		    (ipc_kmsg_queue_first(&rcv_mqueue->imq_messages)
			!= IKM_NULL))
		{
			imq_unlock(rcv_mqueue);
			ip_unlock(reply_port);
			ipc_mqueue_send_always(kmsg);
			goto slow_get_rcv_port;
		}

		/*
		 * We can directly receive this reply.
		 * Since the kernel reply never blocks,
		 * it holds no message_accepted request.
		 * Since there were no messages queued
		 * on the reply port, there should be
		 * no threads blocked waiting to send.
		 */

		assert(kmsg->ikm_marequest == IMAR_NULL);
		assert(ipc_thread_queue_first(&reply_port->ip_blocked)
				== ITH_NULL);

		dest_port = reply_port;
		kmsg->ikm_header.msgh_seqno = dest_port->ip_seqno++;
		imq_unlock(rcv_mqueue);

		/*
		 * inline ipc_object_release.
		 * Port is still locked.
		 * Reference count was not incremented.
		 */
		ip_check_unlock(reply_port);

		/* copy out the kernel reply */
		goto fast_copyout;
	    }

	    slow_send:
		/*
		 *	Nothing is locked.  We have acquired kmsg, but
		 *	we still need to send it and receive a reply.
		 */

		mr = ipc_mqueue_send(kmsg, MACH_MSG_OPTION_NONE,
				     MACH_MSG_TIMEOUT_NONE);
		if (mr != MACH_MSG_SUCCESS) {
			mr |= ipc_kmsg_copyout_pseudo(kmsg, space,
						      current_map());

			assert(kmsg->ikm_marequest == IMAR_NULL);
			(void) ipc_kmsg_put(msg, kmsg,
					    kmsg->ikm_header.msgh_size);
			thread_syscall_return(mr);
			/*NOTREACHED*/
		}

	    slow_get_rcv_port:
		/*
		 * We have sent the message.  Copy in the receive port.
		 */
		mr = ipc_mqueue_copyin(space, rcv_name,
				       &temp_rcv_mqueue, &temp_rcv_object);
		if (mr != MACH_MSG_SUCCESS) {
			thread_syscall_return(mr);
			/*NOTREACHED*/
		}
		rcv_mqueue = temp_rcv_mqueue;
		rcv_object = temp_rcv_object;
		/* hold ref for rcv_object; rcv_mqueue is locked */

	/*
	    slow_receive:
	*/
		/*
		 *	Now we have sent the request and copied in rcv_name,
		 *	so rcv_mqueue is locked and hold ref for rcv_object.
		 *	Just receive a reply and try to get back to fast path.
		 *
		 *	ipc_mqueue_receive may not return, because if we block
		 *	then our kernel stack may be discarded.  So we save
		 *	state here for mach_msg_continue to pick up.
		 */

		self->ith_msg = msg;
		self->ith_rcv_size = rcv_size;
		self->ith_object = rcv_object;
		self->ith_mqueue = rcv_mqueue;

		mr = ipc_mqueue_receive(rcv_mqueue,
					MACH_MSG_OPTION_NONE,
					MACH_MSG_SIZE_MAX,
					MACH_MSG_TIMEOUT_NONE,
					FALSE, mach_msg_continue,
		       			&temp_kmsg, &temp_seqno);
		/* rcv_mqueue is unlocked */
		ipc_object_release(rcv_object);
		if (mr != MACH_MSG_SUCCESS) {
			thread_syscall_return(mr);
			/*NOTREACHED*/
		}

		(kmsg = temp_kmsg)->ikm_header.msgh_seqno = temp_seqno;
		dest_port = (ipc_port_t) kmsg->ikm_header.msgh_remote_port;
		goto fast_copyout;

	    slow_copyout:
		/*
		 *	Nothing locked and no references held, except
		 *	we have kmsg with msgh_seqno filled in.  Must
		 *	still check against rcv_size and do
		 *	ipc_kmsg_copyout/ipc_kmsg_put.
		 */

		reply_size = kmsg->ikm_header.msgh_size;
		if (rcv_size < reply_size) {
			ipc_kmsg_copyout_dest(kmsg, space);
			(void) ipc_kmsg_put(msg, kmsg, sizeof *msg);
			thread_syscall_return(MACH_RCV_TOO_LARGE);
			/*NOTREACHED*/
		}

		mr = ipc_kmsg_copyout(kmsg, space, current_map(),
				      MACH_PORT_NULL);
		if (mr != MACH_MSG_SUCCESS) {
			if ((mr &~ MACH_MSG_MASK) == MACH_RCV_BODY_ERROR) {
				(void) ipc_kmsg_put(msg, kmsg,
						kmsg->ikm_header.msgh_size);
			} else {
				ipc_kmsg_copyout_dest(kmsg, space);
				(void) ipc_kmsg_put(msg, kmsg, sizeof *msg);
			}

			thread_syscall_return(mr);
			/*NOTREACHED*/
		}

		/* try to get back on optimized path */

		goto fast_put;

	    slow_put:
		mr = ipc_kmsg_put(msg, kmsg, reply_size);
		thread_syscall_return(mr);
		/*NOTREACHED*/
	    }
	} else if (option == MACH_SEND_MSG) {
		ipc_space_t space = current_space();
		vm_map_t map = current_map();
		ipc_kmsg_t kmsg;

		mr = ipc_kmsg_get(msg, send_size, &kmsg);
		if (mr != MACH_MSG_SUCCESS)
			return mr;

		mr = ipc_kmsg_copyin(kmsg, space, map, MACH_PORT_NULL);
		if (mr != MACH_MSG_SUCCESS) {
			ikm_free(kmsg);
			return mr;
		}

		mr = ipc_mqueue_send(kmsg, MACH_MSG_OPTION_NONE,
				     MACH_MSG_TIMEOUT_NONE);
		if (mr != MACH_MSG_SUCCESS) {
			mr |= ipc_kmsg_copyout_pseudo(kmsg, space, map);

			assert(kmsg->ikm_marequest == IMAR_NULL);
			(void) ipc_kmsg_put(msg, kmsg,
					    kmsg->ikm_header.msgh_size);
		}

		return mr;
	} else if (option == MACH_RCV_MSG) {
		ipc_thread_t self = current_thread();
		ipc_space_t space = current_space();
		vm_map_t map = current_map();
		ipc_object_t object;
		ipc_mqueue_t mqueue;
		ipc_kmsg_t kmsg;
		mach_port_seqno_t seqno;

		mr = ipc_mqueue_copyin(space, rcv_name, &mqueue, &object);
		if (mr != MACH_MSG_SUCCESS)
			return mr;
		/* hold ref for object; mqueue is locked */

		/*
		 *	ipc_mqueue_receive may not return, because if we block
		 *	then our kernel stack may be discarded.  So we save
		 *	state here for mach_msg_continue to pick up.
		 */

		self->ith_msg = msg;
		self->ith_rcv_size = rcv_size;
		self->ith_object = object;
		self->ith_mqueue = mqueue;

		mr = ipc_mqueue_receive(mqueue,
					MACH_MSG_OPTION_NONE,
					MACH_MSG_SIZE_MAX,
					MACH_MSG_TIMEOUT_NONE,
					FALSE, mach_msg_continue,
					&kmsg, &seqno);
		/* mqueue is unlocked */
		ipc_object_release(object);
		if (mr != MACH_MSG_SUCCESS)
			return mr;

		kmsg->ikm_header.msgh_seqno = seqno;
		if (rcv_size < kmsg->ikm_header.msgh_size) {
			ipc_kmsg_copyout_dest(kmsg, space);
			(void) ipc_kmsg_put(msg, kmsg, sizeof *msg);
			return MACH_RCV_TOO_LARGE;
		}

		mr = ipc_kmsg_copyout(kmsg, space, map, MACH_PORT_NULL);
		if (mr != MACH_MSG_SUCCESS) {
			if ((mr &~ MACH_MSG_MASK) == MACH_RCV_BODY_ERROR) {
				(void) ipc_kmsg_put(msg, kmsg,
						kmsg->ikm_header.msgh_size);
			} else {
				ipc_kmsg_copyout_dest(kmsg, space);
				(void) ipc_kmsg_put(msg, kmsg, sizeof *msg);
			}

			return mr;
		}

		return ipc_kmsg_put(msg, kmsg, kmsg->ikm_header.msgh_size);
	} else if (option == MACH_MSG_OPTION_NONE) {
		/*
		 *	We can measure the "null mach_msg_trap"
		 *	(syscall entry and thread_syscall_return exit)
		 *	with this path.
		 */

		thread_syscall_return(MACH_MSG_SUCCESS);
		/*NOTREACHED*/
	}

	if (option & MACH_SEND_MSG) {
		mr = mach_msg_send(msg, option, send_size,
				   time_out, notify);
		if (mr != MACH_MSG_SUCCESS)
			return mr;
	}

	if (option & MACH_RCV_MSG) {
		mr = mach_msg_receive(msg, option, rcv_size, rcv_name,
				      time_out, notify);
		if (mr != MACH_MSG_SUCCESS)
			return mr;
	}

	return MACH_MSG_SUCCESS;
}
Exemplo n.º 27
0
boolean_t
ipc_port_check_circularity(
	ipc_port_t	port,
	ipc_port_t	dest)
{
	ipc_port_t base;

#if IMPORTANCE_INHERITANCE
	task_t task = TASK_NULL;
	task_t release_task = TASK_NULL;
	int assertcnt = 0;
#endif /* IMPORTANCE_INHERITANCE */

	assert(port != IP_NULL);
	assert(dest != IP_NULL);

	if (port == dest)
		return TRUE;
	base = dest;

	/*
	 *	First try a quick check that can run in parallel.
	 *	No circularity if dest is not in transit.
	 */

	ip_lock(port);
	if (ip_lock_try(dest)) {
		if (!ip_active(dest) ||
		    (dest->ip_receiver_name != MACH_PORT_NULL) ||
		    (dest->ip_destination == IP_NULL))
			goto not_circular;

		/* dest is in transit; further checking necessary */

		ip_unlock(dest);
	}
	ip_unlock(port);

	ipc_port_multiple_lock(); /* massive serialization */

	/*
	 *	Search for the end of the chain (a port not in transit),
	 *	acquiring locks along the way.
	 */

	for (;;) {
		ip_lock(base);

		if (!ip_active(base) ||
		    (base->ip_receiver_name != MACH_PORT_NULL) ||
		    (base->ip_destination == IP_NULL))
			break;

		base = base->ip_destination;
	}

	/* all ports in chain from dest to base, inclusive, are locked */

	if (port == base) {
		/* circularity detected! */

		ipc_port_multiple_unlock();

		/* port (== base) is in limbo */

		assert(ip_active(port));
		assert(port->ip_receiver_name == MACH_PORT_NULL);
		assert(port->ip_destination == IP_NULL);

		while (dest != IP_NULL) {
			ipc_port_t next;

			/* dest is in transit or in limbo */

			assert(ip_active(dest));
			assert(dest->ip_receiver_name == MACH_PORT_NULL);

			next = dest->ip_destination;
			ip_unlock(dest);
			dest = next;
		}

		return TRUE;
	}

	/*
	 *	The guarantee:  lock port while the entire chain is locked.
	 *	Once port is locked, we can take a reference to dest,
	 *	add port to the chain, and unlock everything.
	 */

	ip_lock(port);
	ipc_port_multiple_unlock();

    not_circular:

	/* port is in limbo */

	assert(ip_active(port));
	assert(port->ip_receiver_name == MACH_PORT_NULL);
	assert(port->ip_destination == IP_NULL);

	ip_reference(dest);
	port->ip_destination = dest;

#if IMPORTANCE_INHERITANCE
	/* must have been in limbo or still bound to a task */
	assert(port->ip_tempowner != 0);

	if (port->ip_taskptr != 0) {
		/*
		 * We delayed dropping assertions from a specific task.
		 * Cache that info now (we'll drop assertions and the
		 * task reference below).
		 */
		release_task = port->ip_imp_task;
		port->ip_imp_task = TASK_NULL;
		port->ip_taskptr = 0;
	}
	assertcnt = port->ip_impcount;

	/* take the port out of limbo w.r.t. assertions */
	port->ip_tempowner = 0;

#endif /* IMPORTANCE_INHERITANCE */

	/* now unlock chain */

	ip_unlock(port);

	for (;;) {

#if IMPORTANCE_INHERITANCE
		/* every port along chain track assertions behind it */
		dest->ip_impcount += assertcnt;
#endif /* IMPORTANCE_INHERITANCE */

		if (dest == base)
			break;

		/* port is in transit */

		assert(ip_active(dest));
		assert(dest->ip_receiver_name == MACH_PORT_NULL);
		assert(dest->ip_destination != IP_NULL);

#if IMPORTANCE_INHERITANCE
		assert(dest->ip_tempowner == 0);
#endif /* IMPORTANCE_INHERITANCE */

		port = dest->ip_destination;
		ip_unlock(dest);
		dest = port;
	}

	/* base is not in transit */
	assert(!ip_active(base) ||
	       (base->ip_receiver_name != MACH_PORT_NULL) ||
	       (base->ip_destination == IP_NULL));

#if IMPORTANCE_INHERITANCE
	/*
	 * Find the task to boost (if any).
	 * We will boost "through" ports that don't know
	 * about inheritance to deliver receive rights that
	 * do.
	 */
	if (ip_active(base) && (assertcnt > 0)) {
		if (base->ip_tempowner != 0) {
			if (base->ip_taskptr != 0)
				/* specified tempowner task */
				task = base->ip_imp_task;
			/* otherwise don't boost current task */

		} else if (base->ip_receiver_name != MACH_PORT_NULL) {
			ipc_space_t space = base->ip_receiver;

			/* only spaces with boost-accepting tasks */
			if (space->is_task != TASK_NULL &&
			    space->is_task->imp_receiver != 0)
				task = space->is_task;
		}

		/* take reference before unlocking base */
		if (task != TASK_NULL) {
			assert(task->imp_receiver != 0);
			task_reference(task);
		}
	}
#endif /* IMPORTANCE_INHERITANCE */

	ip_unlock(base);

#if IMPORTANCE_INHERITANCE
	/*
	 * Transfer assertions now that the ports are unlocked.
	 * Avoid extra overhead if transferring to/from the same task.
	 */
	boolean_t transfer_assertions = (task != release_task) ? TRUE : FALSE;

	if (task != TASK_NULL) {
		if (transfer_assertions)
			task_importance_hold_internal_assertion(task, assertcnt);
		task_deallocate(task);
		task = TASK_NULL;
	}

	if (release_task != TASK_NULL) {
		if (transfer_assertions)
			task_importance_drop_internal_assertion(release_task, assertcnt);
		task_deallocate(release_task);
		release_task = TASK_NULL;
	}
#endif /* IMPORTANCE_INHERITANCE */

	return FALSE;
}