Is accessing/changing dictionary values thread-safe?

I have a global dictionary foo and multiple threads with ids id1, id2, ... , idn. Is it OK to access and change foo's values without allocating a lock for it if it's known that each thread will only work with its id-related value, say thread with id1 will only work with foo[id1]?

  • You are using CPython, right? Aug 21, 2009 at 14:44
  • @voyager: yes, I'm using CPython.
    – Alex
    Aug 21, 2009 at 15:30

5 Answers 5


Assuming CPython: Yes and no. It is actually safe to fetch/store values from a shared dictionary in the sense that multiple concurrent read/write requests won't corrupt the dictionary. This is due to the global interpreter lock ("GIL") maintained by the implementation. That is:

Thread A running:

a = global_dict["foo"]

Thread B running:

global_dict["bar"] = "hello"

Thread C running:

global_dict["baz"] = "world"

won't corrupt the dictionary, even if all three access attempts happen at the "same" time. The interpreter will serialize them in some undefined way.

However, the results of the following sequence is undefined:

Thread A:

if "foo" not in global_dict:
   global_dict["foo"] = 1

Thread B:

global_dict["foo"] = 2

as the test/set in thread A is not atomic ("time-of-check/time-of-use" race condition). So, it is generally best, if you lock things:

from threading import RLock

lock = RLock()

def thread_A():
    with lock:
        if "foo" not in global_dict:
            global_dict["foo"] = 1

def thread_B():
    with lock:
        global_dict["foo"] = 2
  • Would global_dict.setdefault("foo", 1) in Thread A make the need for a lock unnecessary?
    – Claudiu
    Jun 13, 2012 at 15:40
  • 1
    Am I understanding this correctly. As long as im adding to the dictionary without modification, it is safe. ie dict['a'] = 1 in thread a and dict['b'] = 2 in thread b is okay because keys a and b are not the same?
    – Cripto
    Jul 22, 2013 at 11:34
  • 1
    @user1048138 -- No. What's safe and what's not depends on your application. Think about a class, which has the fields a and b and the invariant, that exactly one of those fields is not None and the other is None. Unless access is properly interlocked, any random combination of a is [not] None and b is [not] None may be observable in clear violation of the invariant, if only a "naive" getter/setter is used (think: def set_a(self,a): self.a = a; self.b = None if a is not None else self.b -- a concurrent thread may observe illegal states during the execution)
    – Dirk
    Jul 22, 2013 at 13:11
  • is there a way for me to place the lock on the dictionary datastructure's write/update/delete? Sep 10, 2013 at 21:26
  • 2
    @Claudiu: setdefault will initialize atomically in CPython if the key is composed entirely of builtins implemented in C. The GIL protects you from races so long as the mutating part of an operation occurs with no byte codes in between beginning the mutation and completing it, and in the case of key insertion, you get that behavior when the __eq__ and __hash__ of an object are implemented in C, not Python level code. Dec 29, 2015 at 21:22

The best, safest, portable way to have each thread work with independent data is:

import threading
tloc = threading.local()

Now each thread works with a totally independent tloc object even though it's a global name. The thread can get and set attributes on tloc, use tloc.__dict__ if it specifically needs a dictionary, etc.

Thread-local storage for a thread goes away at end of thread; to have threads record their final results, have them put their results, before they terminate, into a common instance of Queue.Queue (which is intrinsically thread-safe). Similarly, initial values for data a thread is to work on could be arguments passed when the thread is started, or be taken from a Queue.

Other half-baked approaches, such as hoping that operations that look atomic are indeed atomic, may happen to work for specific cases in a given version and release of Python, but could easily get broken by upgrades or ports. There's no real reason to risk such issues when a proper, clean, safe architecture is so easy to arrange, portable, handy, and fast.

  • 2
    Thread-local storage is both extreme overkill and invites non-trivial complexities (e.g., due to the the need to recombine thread-local results) for simple situations like this. As suggested by saner answers, just: (A) globally declare a dict_lock = threading.Lock() or dict_lock = threading.RLock() and (B) wrap each dictionary access in a with dict_lock: context manager. Oct 19, 2021 at 6:00

Since I needed something similar, I landed here. I sum up your answers in this short snippet :

#!/usr/bin/env python3

import threading

class ThreadSafeDict(dict) :
    def __init__(self, * p_arg, ** n_arg) :
        dict.__init__(self, * p_arg, ** n_arg)
        self._lock = threading.Lock()

    def __enter__(self) :
        return self

    def __exit__(self, type, value, traceback) :

if __name__ == '__main__' :

    u = ThreadSafeDict()
    with u as m :
        m[1] = 'foo'

as such, you can use the with construct to hold the lock while fiddling in your dict()

  • 3
    Obfuscatory boilerplate. Ideally, a class labelled ThreadSafeDict should be an implicitly thread-safe dictionary. This isn't; it's just a pointless thin wrapper around threading.Lock. Callers still have to manually wrap each dictionary operation in an explicit context manager – which is exactly what callers would do anyway with a direct threading.Lock. O_o Oct 19, 2021 at 6:07
  • well, I agree for the boilerplate ^_^; you can change the name you find it obfuscatory. But concerning the implicit thread safe dict, I don't know what would be the best way to write the fact that we can do more than one operation under the same lock....
    – yota
    Jan 10 at 13:05

The GIL takes care of that, if you happen to be using CPython.

global interpreter lock

The lock used by Python threads to assure that only one thread executes in the CPython virtual machine at a time. This simplifies the CPython implementation by assuring that no two processes can access the same memory at the same time. Locking the entire interpreter makes it easier for the interpreter to be multi-threaded, at the expense of much of the parallelism afforded by multi-processor machines. Efforts have been made in the past to create a “free-threaded” interpreter (one which locks shared data at a much finer granularity), but so far none have been successful because performance suffered in the common single-processor case.

See are-locks-unnecessary-in-multi-threaded-python-code-because-of-the-gil.

  • That only concerns CPython though. Aug 21, 2009 at 14:44
  • Unless he happens to be using Jython or IronPython. Aug 21, 2009 at 14:45
  • @Bastien Léonard: Beat me to it :) Aug 21, 2009 at 14:45
  • 4
    This doesn't mean that you can rely on the GIL. The key could be an instance of a class with a __hash__ method, so more than 1 Python bytecode instruction is executed and the thread can switch anyway. Then there are I/O operations and native code sections that release the GIL. Locks are still very much a requirement for thread-safe code.
    – Martijn Pieters
    Dec 29, 2015 at 21:17

How it works?:

>>> import dis
>>> demo = {}
>>> def set_dict():
...     demo['name'] = 'Jatin Kumar'
>>> dis.dis(set_dict)
  2           0 LOAD_CONST               1 ('Jatin Kumar')
              3 LOAD_GLOBAL              0 (demo)
              6 LOAD_CONST               2 ('name')
              9 STORE_SUBSCR
             10 LOAD_CONST               0 (None)
             13 RETURN_VALUE

Each of the above instructions is executed with GIL lock hold and STORE_SUBSCR instruction adds/updates the key+value pair in a dictionary. So you see that dictionary update is atomic and hence thread safe.

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