Reading through the Python docs I came across RLock.

Can someone explain to me (with example) a scenario in which RLock would be preferred to Lock?

With particular reference to:

  • RLock's “recursion level”. How is this useful?
  • A threads "ownership" of an RLock object
  • Performance?

3 Answers 3


This is one example where I see the use:

Useful when

  1. you want to have thread-safe access from outside the class and use the same methods from inside the class:

    class X:
        def __init__(self):
            self.a = 1
            self.b = 2
            self.lock = threading.RLock()
        def changeA(self):
            with self.lock:
                self.a = self.a + 1
        def changeB(self):
            with self.lock:
                self.b = self.b + self.a
        def changeAandB(self):
            # you can use chanceA and changeB thread-safe!
            with self.lock:
                self.changeA() # a usual lock would block at here
  2. for recursion more obvious:

    lock = threading.RLock()
    def a(...):
         with lock:
             a(...) # somewhere inside

    other threads have to wait until the first call of a finishes = thread ownership.


Usually, I start programming with the Lock and when case 1 or 2 occur, I switch to an RLock. Until Python 3.2 the RLock should be a bit slower because of the additional code. It uses Lock:

Lock = _allocate_lock # line 98 threading.py

def RLock(*args, **kwargs):
    return _RLock(*args, **kwargs)

class _RLock(_Verbose):

    def __init__(self, verbose=None):
        _Verbose.__init__(self, verbose)
        self.__block = _allocate_lock()

Thread Ownership

within the given thread you can acquire a RLock as often as you like. Other threads need to wait until this thread releases the resource again.

This is different to the Lock which implies 'function-call ownership'(I would call it this way): Another function call has to wait until the resource is released by the last blocking function even if it is in the same thread = even if it is called by the other function.

When to use Lock instead of RLock

When you make a call to the outside of the resource which you can not control.

The code below has two variables: a and b and the RLock shall be used to make sure a == b * 2

import threading
a = 0 
b = 0
lock = threading.RLock()
def changeAandB(): 
    # this function works with an RLock and Lock
    with lock:
        global a, b
        a += 1
        b += 2
        return a, b

def changeAandB2(callback):
    # this function can return wrong results with RLock and can block with Lock
    with lock:
        global a, b
        a += 1
        callback() # this callback gets a wrong value when calling changeAandB2
        b += 2
        return a, b

In changeAandB2 the Lock would be the right choice although it does block. Or one can enhance it with errors using RLock._is_owned(). Functions like changeAandB2 may occur when you have implemented an Observer pattern or a Publisher-Subscriber and add locking afterward.

  • Great answer! Is _is_owned documented anywhere? I was expecting some kind of owner_name attribute or method but cannot find anything documented
    – Awalias
    Commented May 16, 2013 at 10:24
  • _is_owned() starts with an underscore and therefore one is not expected to use it. (It returns the tread id of sys._current_treads().) require(False) is nonblocking and enough in most cases.
    – User
    Commented May 16, 2013 at 10:29
  • 5
    For future readers, in Python 3.2 and higher, the performance cost of RLock is basically zero, because RLock is implemented in C just like Lock; previously, it was slower because it executed a lot of Python code to wrap Lock, but in 3.2+, there is no cost (aside from Lock being unlockable from other threads, where RLock is only unlockable by the owner, which is a meaningful distinction in stuff like the implementation of Condition which uses cross-thread unlocks to notify waiters). Commented Oct 15, 2015 at 20:21
  • Lock is being used in ratelimit library github.com/tomasbasham/ratelimit/blob/master/ratelimit/… Commented Nov 13, 2019 at 7:15
  • 1
    In changeAandB2, the line with callback() # this callback gets a wrong value when calling changeAandB2 did you mean to say changeAandB2 or changeAandB? Because if you invoke changeAandB2 with a callback of changeAandB2 then an error will be raised since changeAandB2 can't be invoked without its callback argument supplied.
    – Willwsharp
    Commented Jan 22, 2020 at 14:43
  • recursion level
  • ownership

A primitive lock (Lock) is a synchronization primitive that is not owned by a particular thread when locked.

For the repeatable Lock (RLock) In the locked state, some thread owns the lock; in the unlocked state, no thread owns it. When invoked if this thread already owns the lock, increment the recursion level by one, and return immediately. if thread doesn't own the lock It waits until owner release lock. Release a lock, decrementing the recursion level. If after the decrement it is zero, reset the lock to unlocked.

  • Performance

I don't think there is some performance difference rather conceptual one.


Here is another use case for RLock. Suppose you have a web-facing user interface that supports concurrent access, but you need to manage certain kinds of access to an external resource. For instance, you have to maintain consistency between objects in memory and objects in a database, and you have a manager class that controls access to the database, with methods that you must ensure get called in a specific order, and never concurrently.

What you can do is create an RLock and a guardian thread that controls access to the RLock by constantly acquiring it, and releasing only when signaled to. Then, you ensure all methods you need to control access to are made to obtain the lock before they run. Something like this:

def guardian_func():
    while True:

class WebFacingInterface(object):
    guardian_allow_access = Event()
    resource_guardian = Thread(None, guardian_func, 'Guardian', [])
    resource_manager = ResourceManager()

    def resource_modifying_method(cls):

class ResourceManager(object):
    resource_lock = RLock()

    def update_this(self):
        if self.resource_lock.acquire(False):
                pass # do something
                return True

            return False

    def update_that(self):
        if self.resource_lock.acquire(False):
                pass # do something else
                return True
            return False

This way, you're ensured of the following things:

  1. Once a thread acquires the resource lock, it can call the resource manager's protected methods freely, because RLock is recursive
  2. Once the thread acquires the resource lock through the master method in the web facing interface, all access to protected methods in the manager will be blocked to other threads
  3. Protected methods in the manager can only be accessed by first appealing to the guardian.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.