from threading import Lock, Thread
class SingletonMeta(type):
"""
This is a thread-safe implementation of Singleton.
"""
_instances = {}
_lock: Lock = Lock()
"""
We now have a lock object that will be used to synchronize threads during
first access to the Singleton.
"""
def __call__(cls, *args, **kwargs):
"""
Possible changes to the value of the `__init__` argument do not affect
the returned instance.
"""
# Now, imagine that the program has just been launched. Since there's no
# Singleton instance yet, multiple threads can simultaneously pass the
# previous conditional and reach this point almost at the same time. The
# first of them will acquire lock and will proceed further, while the
# rest will wait here.
with cls._lock:
# The first thread to acquire the lock, reaches this conditional,
# goes inside and creates the Singleton instance. Once it leaves the
# lock block, a thread that might have been waiting for the lock
# release may then enter this section. But since the Singleton field
# is already initialized, the thread won't create a new object.
if cls not in cls._instances:
instance = super().__call__(*args, **kwargs)
cls._instances[cls] = instance
return cls._instances[cls]
class Singleton(metaclass=SingletonMeta):
value: str = None
"""
We'll use this property to prove that our Singleton really works.
"""
def __init__(self, value: str) -> None:
self.value = value
def some_business_logic(self):
"""
Finally, any singleton should define some business logic, which can be
executed on its instance.
"""
def test_singleton(value: str) -> None:
singleton = Singleton(value)
print(singleton.value)
if __name__ == "__main__":
# The client code.
print("If you see the same value, then singleton was reused (yay!)
"
"If you see different values, "
"then 2 singletons were created (booo!!)
"
"RESULT:
")
process1 = Thread(target=test_singleton, args=("FOO",))
process2 = Thread(target=test_singleton, args=("BAR",))
process1.start()
process2.start()