I want to repeatedly execute a function in Python every 60 seconds forever (just like an NSTimer in Objective C or setTimeout in JS). This code will run as a daemon and is effectively like calling the python script every minute using a cron, but without requiring that to be set up by the user.

In this question about a cron implemented in Python, the solution appears to effectively just sleep() for x seconds. I don't need such advanced functionality so perhaps something like this would work

while True:
    # Code executed here

Are there any foreseeable problems with this code?

  • 129
    A pedantic point, but may be critical, your code above code doesn't execute every 60 seconds it puts a 60 second gap between executions. It only happens every 60 seconds if your executed code takes no time at all.
    – Simon
    Jan 23 '09 at 21:12
  • 6
    also time.sleep(60) may return both earlier and later
    – jfs
    Mar 19 '14 at 7:25
  • 6
    I am still wondering: Are there any foreseeable problems with this code?
    – dwitvliet
    Jan 27 '15 at 18:39
  • 5
    The "foreseeable problem" is you cannot expect 60 iterations per hour by just using time.sleep(60). So if you're appending one item per iteration and keeping a list of set length... the average of that list will not represent a consistent "period" of time; so functions such as "moving average" can be referencing data points that are too old, which will distort your indication. Feb 21 '17 at 14:28
  • 8
    @Banana Yes, you can expect any problems caused because your script is not executed EXACTLY every 60 seconds. For instance. I started doing something like this to split video streams and upload'em, and I ended up getting strems 5-10~ seconds longer because the media queue is buffering while I process data inside the loop. It depends on your data. If the function is some kind of simple watchdog thats warns you, for instance, when your disk is full, you should have no problems at all with this.If you're checking a nuclear power plant warning alerts you may end up with a city completly blown up x
    – DGoiko
    Oct 31 '18 at 11:46

21 Answers 21


If your program doesn't have a event loop already, use the sched module, which implements a general purpose event scheduler.

import sched, time
s = sched.scheduler(time.time, time.sleep)
def do_something(sc): 
    print("Doing stuff...")
    # do your stuff
    s.enter(60, 1, do_something, (sc,))

s.enter(60, 1, do_something, (s,))

If you're already using an event loop library like asyncio, trio, tkinter, PyQt5, gobject, kivy, and many others - just schedule the task using your existing event loop library's methods, instead.

  • 23
    The sched module is for scheduling functions to run after some time, how do you use it to repeat a function call every x seconds without using time.sleep()? Jan 23 '09 at 21:13
  • 2
    @Baishampayan: Just schedule a new run.
    – nosklo
    Jan 23 '09 at 21:18
  • 4
    Then apscheduler at packages.python.org/APScheduler should also get a mention at this point.
    – Daniel F
    Jan 27 '13 at 20:06
  • 8
    note: this version may drift. You could use enterabs() to avoid it. Here's a non-drifting version for comparison.
    – jfs
    Oct 28 '14 at 16:45
  • 8
    @JavaSa: because "do your stuff" is not instantaneous and errors from time.sleep may accumulate here. "execute every X seconds" and "execute with a delay of ~X seconds repeatedly" are not the same. See also this comment
    – jfs
    Jan 25 '17 at 15:42

Lock your time loop to the system clock like this:

import time
starttime = time.time()
while True:
    print "tick"
    time.sleep(60.0 - ((time.time() - starttime) % 60.0))
  • 38
    +1. yours and the twisted answer are the only answers that run a function every x seconds. The rest execute the function with a delay of x seconds after each call.
    – jfs
    Sep 18 '14 at 7:09
  • 13
    If you where to add some code to this which took longer than a single second... It would throw the timing out and start to lag behind.. The accepted answer in this case is correct... Anyone can loop a simple print command and have it run every second without delay...
    – Angry 84
    Jan 1 '16 at 22:48
  • 8
    I prefer from time import time, sleep because of the existential implications ;)
    – Will
    Feb 16 '16 at 4:40
  • 17
    Works fantastically. There is no need to subtract your starttime if you begin by syncing it to a certain time: time.sleep(60 - time.time() % 60) has been working fine for me. I've used it as time.sleep(1200 - time.time() % 1200) and it gives me logs on the :00 :20 :40, exactly as I wanted. Jul 14 '16 at 19:22
  • 2
    @AntonSchigur to avoid drift after multiple iterations. An individual iteration may start slightly sooner or later depending on sleep(), timer() precision and how long it takes to execute the loop body but on average iterations always occur on the interval boundaries (even if some are skipped): while keep_doing_it(): sleep(interval - timer() % interval). Compare it with just while keep_doing_it(): sleep(interval) where errors may accumulate after several iterations.
    – jfs
    Aug 1 '16 at 20:51

If you want a non-blocking way to execute your function periodically, instead of a blocking infinite loop I'd use a threaded timer. This way your code can keep running and perform other tasks and still have your function called every n seconds. I use this technique a lot for printing progress info on long, CPU/Disk/Network intensive tasks.

Here's the code I've posted in a similar question, with start() and stop() control:

from threading import Timer

class RepeatedTimer(object):
    def __init__(self, interval, function, *args, **kwargs):
        self._timer     = None
        self.interval   = interval
        self.function   = function
        self.args       = args
        self.kwargs     = kwargs
        self.is_running = False

    def _run(self):
        self.is_running = False
        self.function(*self.args, **self.kwargs)

    def start(self):
        if not self.is_running:
            self._timer = Timer(self.interval, self._run)
            self.is_running = True

    def stop(self):
        self.is_running = False


from time import sleep

def hello(name):
    print "Hello %s!" % name

print "starting..."
rt = RepeatedTimer(1, hello, "World") # it auto-starts, no need of rt.start()
    sleep(5) # your long-running job goes here...
    rt.stop() # better in a try/finally block to make sure the program ends!


  • Standard library only, no external dependencies
  • start() and stop() are safe to call multiple times even if the timer has already started/stopped
  • function to be called can have positional and named arguments
  • You can change interval anytime, it will be effective after next run. Same for args, kwargs and even function!
  • This solution seems to drift over time; I needed a version that aims to call the function every n seconds without drift. I'll post an update in a separate question.
    – eraoul
    Dec 5 '16 at 0:21
  • In def _run(self) I am trying to wrap my head around why you call self.start() before self.function(). Can you elaborate? I would think by calling start() first self.is_running would always be False so then we would always spin up a new thread. Dec 21 '16 at 20:08
  • 2
    I think I got to the bottom of it. @MestreLion's solution runs a function every x seconds (i.e. t=0, t=1x, t=2x, t=3x, ...) where at the original posters sample code runs a function with x second interval in between. Also, this solution I believe has a bug if interval is shorter than the time it takes function to execute. In that case, self._timer will get overwritten in the start function. Dec 21 '16 at 23:09
  • Yes, @RichieEpiscopo, the call to .function() after .start() is to run the function at t=0. And I don't think it will be a problem if function takes longer than interval, but yes there might be some racing conditions on the code.
    – MestreLion
    Feb 6 '17 at 15:12
  • 1
    @eraoul : yes, this solution does drift, although it takes a few hundred or even a couple thousand runs before it drifts a single second, depending on your system. If such drift is relevant to you I strongly suggest using a proper system scheduler such as cron
    – MestreLion
    Apr 24 '19 at 16:06

You might want to consider Twisted which is a Python networking library that implements the Reactor Pattern.

from twisted.internet import task, reactor

timeout = 60.0 # Sixty seconds

def doWork():
    #do work here

l = task.LoopingCall(doWork)
l.start(timeout) # call every sixty seconds


While "while True: sleep(60)" will probably work Twisted probably already implements many of the features that you will eventually need (daemonization, logging or exception handling as pointed out by bobince) and will probably be a more robust solution

  • Great answer as well, very accurate without drift. I wonder if this puts the CPU to sleep as well while waiting to execute the task (a.k.a. not busy-waiting)?
    – smoothware
    Apr 16 '19 at 21:37
  • 2
    this drifts at the millisecond level
    – Derek Eden
    Jul 25 '19 at 0:56
  • 1
    What does "drifts at the millisecond level" mean? May 12 '20 at 12:44
  • 1
    Is there anyway to break the loop, lets say after 10 minutes? @Aaron Maenpaa
    – alper
    Jun 24 '20 at 17:46
  • 1
    twisted is super cool but it seems like overkill for the particular problem described.
    – eraoul
    Jul 18 '20 at 2:01

Here's an update to the code from MestreLion that avoids drifiting over time.

The RepeatedTimer class here calls the given function every "interval" seconds as requested by the OP; the schedule doesn't depend on how long the function takes to execute. I like this solution since it doesn't have external library dependencies; this is just pure python.

import threading 
import time

class RepeatedTimer(object):
  def __init__(self, interval, function, *args, **kwargs):
    self._timer = None
    self.interval = interval
    self.function = function
    self.args = args
    self.kwargs = kwargs
    self.is_running = False
    self.next_call = time.time()

  def _run(self):
    self.is_running = False
    self.function(*self.args, **self.kwargs)

  def start(self):
    if not self.is_running:
      self.next_call += self.interval
      self._timer = threading.Timer(self.next_call - time.time(), self._run)
      self.is_running = True

  def stop(self):
    self.is_running = False

Sample usage (copied from MestreLion's answer):

from time import sleep

def hello(name):
    print "Hello %s!" % name

print "starting..."
rt = RepeatedTimer(1, hello, "World") # it auto-starts, no need of rt.start()
    sleep(5) # your long-running job goes here...
    rt.stop() # better in a try/finally block to make sure the program ends!
  • 1
    I agree this is the best - no 3rd party packages and I have tested that it doesn't drift over time
    – Elendurwen
    Jul 13 at 18:46

The easier way I believe to be:

import time

def executeSomething():
    #code here

while True:

This way your code is executed, then it waits 60 seconds then it executes again, waits, execute, etc... No need to complicate things :D

  • 48
    Actually this is not the answer : time sleep() can only be used for waiting X seconds after every execution. For example , if your function takes 0.5 seconds to execute and you use time.sleep(1) , it means your function executes every 1.5 seconds , not 1. You should use other modules and/or threads to make sure something works for Y times in every X second. Sep 18 '13 at 10:09
  • 1
    @kommradHomer: Dave Rove's answer demonstrates that you can use time.sleep() run something every X seconds
    – jfs
    Sep 21 '14 at 4:56
  • 2
    In my opinion the code should call time.sleep() in while True loop like: def executeSomething(): print('10 sec left') ; while True: executeSomething(); time.sleep(10) Nov 17 '17 at 13:09
import time, traceback

def every(delay, task):
  next_time = time.time() + delay
  while True:
    time.sleep(max(0, next_time - time.time()))
    except Exception:
      # in production code you might want to have this instead of course:
      # logger.exception("Problem while executing repetitive task.")
    # skip tasks if we are behind schedule:
    next_time += (time.time() - next_time) // delay * delay + delay

def foo():
  print("foo", time.time())

every(5, foo)

If you want to do this without blocking your remaining code, you can use this to let it run in its own thread:

import threading
threading.Thread(target=lambda: every(5, foo)).start()

This solution combines several features rarely found combined in the other solutions:

  • Exception handling: As far as possible on this level, exceptions are handled properly, i. e. get logged for debugging purposes without aborting our program.
  • No chaining: The common chain-like implementation (for scheduling the next event) you find in many answers is brittle in the aspect that if anything goes wrong within the scheduling mechanism (threading.Timer or whatever), this will terminate the chain. No further executions will happen then, even if the reason of the problem is already fixed. A simple loop and waiting with a simple sleep() is much more robust in comparison.
  • No drift: My solution keeps an exact track of the times it is supposed to run at. There is no drift depending on the execution time (as in many other solutions).
  • Skipping: My solution will skip tasks if one execution took too much time (e. g. do X every five seconds, but X took 6 seconds). This is the standard cron behavior (and for a good reason). Many other solutions then simply execute the task several times in a row without any delay. For most cases (e. g. cleanup tasks) this is not wished. If it is wished, simply use next_time += delay instead.
  • 2
    best answer for not drifting. Sep 16 '18 at 13:59
  • 1
    @PirateApp I would do this in a different thread. You could do it in the same thread but then you end up programming your own scheduling system which is way too complex for a comment.
    – Alfe
    Feb 21 '19 at 9:33
  • 2
    In Python, thanks to the GIL, accessing variables in two threads is perfectly safe. And mere reading in two threads should never be a problem (also not in other threaded environments). Only writing from two different threads in a system without a GIL (e. g. in Java, C++, etc.) needs some explicit synchronization.
    – Alfe
    Feb 21 '19 at 9:38
  • 1
    @user50473 Without any further information I would first approach the task from the threaded side. One thread reads the data now and then and then sleeps until it's time again to do it. The solution above could be used to do this of course. But I could imagine a bunch of reasons to go a different way. So good luck :)
    – Alfe
    Oct 15 '19 at 13:20
  • 1
    Sleep can be replace by threading.Event wait with timeout to be more responsive on application exit. stackoverflow.com/questions/29082268/…
    – themadmax
    Dec 24 '19 at 14:39

I ended up using the schedule module. The API is nice.

import schedule
import time

def job():
    print("I'm working...")


while True:
  • 1
    I'm having a hard time trying to use this module in particular, I need to unblock the main thread, I've checked the FAQ in the schedule's documentation website, but I didn't really understand the workaround supplied. Does anyone know where I can find a working example that doesn't block the main thread?
    – user12725052
    Jan 30 '20 at 13:24
  • 2
    use gevent.spawn() to have it not block your main thread. I call a method that handles all of my scheduler initialization through that and it works absolutely great. Dec 2 '20 at 16:29
  • To have a function run every so many minutes at the beginning of the minute, the following works well: schedule.every(MIN_BETWEEN_IMAGES).minutes.at(":00").do(run_function) where MIN_BETWEEN_IMAGES is the number of minutes and run_function is the function to run. Jul 6 at 16:52

The main difference between that and cron is that an exception will kill the daemon for good. You might want to wrap with an exception catcher and logger.


I faced a similar problem some time back. May be http://cronus.readthedocs.org might help?

For v0.2, the following snippet works

import cronus.beat as beat

beat.set_rate(2) # 2 Hz
while beat.true():
    # do some time consuming work here
    beat.sleep() # total loop duration would be 0.5 sec

Alternative flexibility solution is Apscheduler.

pip install apscheduler
from apscheduler.schedulers.background import BlockingScheduler
def print_t():

sched = BlockingScheduler()
sched.add_job(print_t, 'interval', seconds =60) #will do the print_t work for every 60 seconds


Also, apscheduler provides so many schedulers as follow.

  • BlockingScheduler: use when the scheduler is the only thing running in your process

  • BackgroundScheduler: use when you’re not using any of the frameworks below, and want the scheduler to run in the background inside your application

  • AsyncIOScheduler: use if your application uses the asyncio module

  • GeventScheduler: use if your application uses gevent

  • TornadoScheduler: use if you’re building a Tornado application

  • TwistedScheduler: use if you’re building a Twisted application

  • QtScheduler: use if you’re building a Qt application


Simply use

import time

while True:
    print("this will run after every 30 sec")
    #Your code here
  • 1
    this blocks the entire thread execution
    – Divek John
    Sep 27 at 4:57

If drift is not a concern

import threading, time

def print_every_n_seconds(n=2):
    while True:
thread = threading.Thread(target=print_every_n_seconds, daemon=True)

Which asynchronously outputs.

#Tue Oct 16 17:29:40 2018
#Tue Oct 16 17:29:42 2018
#Tue Oct 16 17:29:44 2018

If the task being run takes appreciable amount of time, then the interval becomes 2 seconds + task time, so if you need precise scheduling then this is not for you.

Note the daemon=True flag means this thread won't block the app from shutting down. For example, had issue where pytest would hang indefinitely after running tests waiting for this thead to cease.

  • 2
    No, it prints only the first datetime and then stops...
    – Alex Poca
    Jun 16 '20 at 9:52
  • Are you sure - I just copy and pasted in terminal. It returns right away but the printout continues in background for me. Jun 16 '20 at 14:02
  • It looks like I am missing something here. I copy/pasted the code in test.py, and run with python test.py. With Python2.7 I need to remove daemon=True that's not recognized and I read multiple prints. With Python3.8 it stops after the first print and no process is active after its end. Removing daemon=True I read multiple prints...
    – Alex Poca
    Jun 17 '20 at 7:07
  • 1
    This drifts over time; the sleep only happens after the function's work is done. The OP may expect a more reliable schedule that starts every n seconds.
    – eraoul
    Jul 18 '20 at 1:59
  • 2
    @eraoul I know, my answer does mention that. I've boldened that portion so it stands out better. Jul 18 '20 at 15:11

One possible answer:

import time

while True:
    if time.time()-t>10:
        #run your task here
  • 2
    This is busy waiting an therefore very bad.
    – Alfe
    Apr 12 '18 at 15:57
  • Good solution for someone looking for a non blocking timer.
    – Noel
    Jan 22 '19 at 11:44
  • This is a busy wait. That means the computer will loop as fast as possible on the while True: loop consuming all possible CPU time for a single thread. It is very rare that this is a good solution. May 18 at 0:42

I use Tkinter after() method, which doesn't "steal the game" (like the sched module that was presented earlier), i.e. it allows other things to run in parallel:

import Tkinter

def do_something1():
  global n1
  n1 += 1
  if n1 == 6: # (Optional condition)
    print "* do_something1() is done *"; return
  # Do your stuff here
  # ...
  print "do_something1() "+str(n1)
  tk.after(1000, do_something1)

def do_something2(): 
  global n2
  n2 += 1
  if n2 == 6: # (Optional condition)
    print "* do_something2() is done *"; return
  # Do your stuff here
  # ...
  print "do_something2() "+str(n2)
  tk.after(500, do_something2)

tk = Tkinter.Tk(); 
n1 = 0; n2 = 0

do_something1() and do_something2() can run in parallel and in whatever interval speed. Here, the 2nd one will be executed twice as fast.Note also that I have used a simple counter as a condition to terminate either function. You can use whatever other contition you like or none if you what a function to run until the program terminates (e.g. a clock).

  • Be careful with your wording: after does not allow things to run in parallel. Tkinter is single-threaded and can only do one thing at a time. If something scheduled by after is running, it's not running in parallel with the rest of the code. If both do_something1 and do_something2 are scheduled to run at the same time, they will run sequentially, not in parallel. Mar 14 '18 at 12:23
  • @Apostolos all your solution does is to use the tkinter mainloop instead of sched mainloop, so it works exactly in the same way but allows tkinter interfaces to continue responding. If you're not using tkinter for other things then it doesn't change anything with regard to the sched solution. You can use two or more scheduled functions with different intervals in the sched solution and it will work exactly the same as yours.
    – nosklo
    Mar 15 '18 at 19:39
  • No, it doesn't work the same way. I explained this. The one "locks" the program (i.e. stops the flow, you can't do anything else -- not even starting another scecduled work as you suggest) until it finishes and the other one lets your hands/free free (i.e. you can do other things after it has started. You don't have to wait unti it finishes. This is a huge difference. If you had tried the method I presented, you would have seen for yourself. I have tried yours. Why don't you try mine too?
    – Apostolos
    Mar 19 '18 at 8:17

Here's an adapted version to the code from MestreLion. In addition to the original function, this code:

1) add first_interval used to fire the timer at a specific time(caller need to calculate the first_interval and pass in)

2) solve a race-condition in original code. In the original code, if control thread failed to cancel the running timer("Stop the timer, and cancel the execution of the timer’s action. This will only work if the timer is still in its waiting stage." quoted from https://docs.python.org/2/library/threading.html), the timer will run endlessly.

class RepeatedTimer(object):
def __init__(self, first_interval, interval, func, *args, **kwargs):
    self.timer      = None
    self.first_interval = first_interval
    self.interval   = interval
    self.func   = func
    self.args       = args
    self.kwargs     = kwargs
    self.running = False
    self.is_started = False

def first_start(self):
        # no race-condition here because only control thread will call this method
        # if already started will not start again
        if not self.is_started:
            self.is_started = True
            self.timer = Timer(self.first_interval, self.run)
            self.running = True
    except Exception as e:
        log_print(syslog.LOG_ERR, "timer first_start failed %s %s"%(e.message, traceback.format_exc()))

def run(self):
    # if not stopped start again
    if self.running:
        self.timer = Timer(self.interval, self.run)
    self.func(*self.args, **self.kwargs)

def stop(self):
    # cancel current timer in case failed it's still OK
    # if already stopped doesn't matter to stop again
    if self.timer:
    self.running = False

I use this to cause 60 events per hour with most events occurring at the same number of seconds after the whole minute:

import math
import time
import random

TICK = 60 # one minute tick size
TICK_TIMING = 59 # execute on 59th second of the tick
TICK_MINIMUM = 30 # minimum catch up tick size when lagging

def set_timing():

    now = time.time()
    elapsed = now - info['begin']
    minutes = math.floor(elapsed/TICK)
    tick_elapsed = now - info['completion_time']
    if (info['tick']+1) > minutes:
        wait = max(0,(TICK_TIMING-(time.time() % TICK)))
        print ('standard wait: %.2f' % wait)
    elif tick_elapsed < TICK_MINIMUM:
        wait = TICK_MINIMUM-tick_elapsed
        print ('minimum wait: %.2f' % wait)
        print ('skip set_timing(); no wait')
    drift = ((time.time() - info['begin']) - info['tick']*TICK -
        TICK_TIMING + info['begin']%TICK)
    print ('drift: %.6f' % drift)

info['tick'] = 0
info['begin'] = time.time()
info['completion_time'] = info['begin'] - TICK

while 1:


    print('hello world')

    #random real world event

    info['tick'] += 1
    info['completion_time'] = time.time()

Depending upon actual conditions you might get ticks of length:


but at the end of 60 minutes you'll have 60 ticks; and most of them will occur at the correct offset to the minute you prefer.

On my system I get typical drift of < 1/20th of a second until need for correction arises.

The advantage of this method is resolution of clock drift; which can cause issues if you're doing things like appending one item per tick and you expect 60 items appended per hour. Failure to account for drift can cause secondary indications like moving averages to consider data too deep into the past resulting in faulty output.


e.g., Display current local time

import datetime
import glib
import logger

def get_local_time():
    current_time = datetime.datetime.now().strftime("%H:%M")
    logger.info("get_local_time(): %s",current_time)
    return str(current_time)

def display_local_time():
    logger.info("Current time is: %s", get_local_time())
    return True

# call every minute
glib.timeout_add(60*1000, display_local_time)

Here is another solution without using any extra libaries.

def delay_until(condition_fn, interval_in_sec, timeout_in_sec):
    """Delay using a boolean callable function.

    `condition_fn` is invoked every `interval_in_sec` until `timeout_in_sec`.
    It can break early if condition is met.

        condition_fn     - a callable boolean function
        interval_in_sec  - wait time between calling `condition_fn`
        timeout_in_sec   - maximum time to run

    Returns: None
    start = last_call = time.time()
    while time.time() - start < timeout_in_sec:
        if (time.time() - last_call) > interval_in_sec:
            if condition_fn() is True:
            last_call = time.time()
    ''' tracking number of times it prints'''
import threading

global timeInterval
def printit():
  threading.Timer(timeInterval, printit).start()
  print( "Hello, World!")
  global count

if __name__ == "__main__":
    timeInterval= int(input('Enter Time in Seconds:'))
  • On the basis of user input it will iterate that method at every interval of time.
    – raviGupta
    Aug 28 '18 at 11:11

I think it depends what you want to do and your question didn't specify lots of details.

For me I want to do an expensive operation in one of my already multithreaded processes. So I have that leader process check the time and only her do the expensive op (checkpointing a deep learning model). To do this I increase the counter to make sure 5 then 10 then 15 seconds have passed to save every 5 seconds (or use modular arithmetic with math.floor):

def print_every_5_seconds_have_passed_exit_eventually():
    opts = argparse.Namespace(start=time.time())
    next_time_to_print = 0
    while True:
        current_time_passed = time.time() - opts.start
        if current_time_passed >= next_time_to_print:
            next_time_to_print += 5
            print(f'worked and {current_time_passed=}')
            print(f'{current_time_passed % 5=}')
            print(f'{math.floor(current_time_passed % 5) == 0}')
starting __main__ at __init__
worked and current_time_passed=0.0001709461212158203
current_time_passed % 5=0.0001709461212158203
worked and current_time_passed=5.0
current_time_passed % 5=0.0
worked and current_time_passed=10.0
current_time_passed % 5=0.0
worked and current_time_passed=15.0
current_time_passed % 5=0.0

To me the check of the if statement is what I need. Having threads, schedulers in my already complicated multiprocessing multi-gpu code is not a complexity I want to add if I can avoid it and it seems I can. Checking the worker id is easy to make sure only 1 process is doing this.

Note I used the True print statements to really make sure the modular arithemtic trick worked since checking for exact time is obviously not going to work! But to my pleasant surprised the floor did the trick.

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