Can someone give me an example of why the "send" function associated with Python generator function exists? I fully understand the yield function. However, the send function is confusing to me. The documentation on this method is convoluted:


Resumes the execution and “sends” a value into the generator function. The value argument becomes the result of the current yield expression. The send() method returns the next value yielded by the generator, or raises StopIteration if the generator exits without yielding another value.

What does that mean? I thought value was the input to the function? The phrase "The send() method returns the next value yielded by the generator" seems to be also the exact purpose of the yield function; yield returns the next value yielded by the generator...

Can someone give me an example of a generator utilizing send that accomplishes something yield cannot?


It's used to send values into a generator that just yielded. Here is an artificial (non-useful) explanatory example:

>>> def double_inputs():
...     while True:
...         x = yield
...         yield x * 2
>>> gen = double_inputs()
>>> next(gen)       # run up to the first yield
>>> gen.send(10)    # goes into 'x' variable
>>> next(gen)       # run up to the next yield
>>> gen.send(6)     # goes into 'x' again
>>> next(gen)       # run up to the next yield
>>> gen.send(94.3)  # goes into 'x' again

You can't do this just with yield.

As to why it's useful, one of the best use cases I've seen is Twisted's @defer.inlineCallbacks. Essentially it allows you to write a function like this:

def doStuff():
    result = yield takesTwoSeconds()
    nextResult = yield takesTenSeconds(result * 10)
    defer.returnValue(nextResult / 10)

What happens is that takesTwoSeconds() returns a Deferred, which is a value promising a value will be computed later. Twisted can run the computation in another thread. When the computation is done, it passes it into the deferred, and the value then gets sent back to the doStuff() function. Thus the doStuff() can end up looking more or less like a normal procedural function, except it can be doing all sorts of computations & callbacks etc. The alternative before this functionality would be to do something like:

def doStuff():
    returnDeferred = defer.Deferred()
    def gotNextResult(nextResult):
        returnDeferred.callback(nextResult / 10)
    def gotResult(result):
        takesTenSeconds(result * 10).addCallback(gotNextResult)
    return returnDeferred

It's a lot more convoluted and unwieldy.

  • 2
    Can you explain what the purpose of this is? Why can this not be re-created with double_inputs(startingnumber) and yield? – Tommy Oct 10 '13 at 17:49
  • @Tommy: oh because the values you got has nothing to do with the previous one. let me change the example – Claudiu Oct 10 '13 at 17:51
  • why would you use this then over a simple function that doubles its input?? – Tommy Oct 10 '13 at 17:53
  • 4
    @Tommy: You wouldn't. The first example is just to explain what it does. The second example is for an actually useful use case. – Claudiu Oct 10 '13 at 17:59
  • 1
    @Tommy: I would say if you really wanna know check out this presentation and work through it all. A short answer won't suffice because then you'll just say "But can't I just do it like this?" etc. – Claudiu Oct 10 '13 at 18:45

This function is to write coroutines

def coroutine():
    for i in range(1, 10):
        print("From generator {}".format((yield i)))
c = coroutine()
    while True:
        print("From user {}".format(c.send(1)))
except StopIteration: pass


From generator 1
From user 2
From generator 1
From user 3
From generator 1
From user 4

See how the control is being passed back and forth? Those are coroutines. They can be used for all kinds of cool things like asynch IO and similar.

Think of it like this, with a generator and no send, it's a one way street

==========       yield      ========
Generator |   ------------> | User |
==========                  ========

But with send, it becomes a two way street

==========       yield       ========
Generator |   ------------>  | User |
==========    <------------  ========

Which opens up the door to the user customizing the generators behavior on the fly and the generator responding to the user.

  • 2
    but a generator function can take parameters. How does "Send" go beyond sending a parameter to the generator? – Tommy Oct 10 '13 at 17:57
  • 10
    @Tommy Because you can't change the parameters to a generator as it runs. You give it parameters, it runs, done. With send, you give it parameters, it runs for a bit, you send it a value and it does something different, repeat – Daniel Gratzer Oct 10 '13 at 18:00
  • 2
    @Tommy This will restart the generator, which will cause you to redo lots of work – Daniel Gratzer Oct 10 '13 at 18:06
  • 5
    Could you please explain the purpose of sending a None before everything? – Shubham Aggarwal Jan 19 '16 at 9:48
  • 2
    @ShubhamAggarwal It is done to 'start' the generator. It is just something that needs to be done. It makes some sense when you think about it since the first time you call send() the generator has not reached the keyword yield yet. – Michael Jan 28 '17 at 3:07

This may help someone. Here is a generator that is unaffected by send function. It takes in the number parameter on instantiation and is unaffected by send:

>>> def double_number(number):
...     while True:
...         number *=2 
...         yield number
>>> c = double_number(4)
>>> c.send(None)
>>> c.next()
>>> c.next()
>>> c.send(8)
>>> c.send(8)
>>> c.send(8)

Now here is how you would do the same type of function using send, so on each iteration you can change the value of number:

def double_number(number):
    while True:
        number *= 2
        number = yield number

Here is what that looks like, as you can see sending a new value for number changes the outcome:

>>> def double_number(number):
...     while True:
...         number *= 2
...         number = yield number
>>> c = double_number(4)
>>> c.send(None)
>>> c.send(5) #10
>>> c.send(1500) #3000
>>> c.send(3) #6

You can also put this in a for loop as such:

for x in range(10):
    n = c.send(n)
    print n

For more help check out this great tutorial.

  • 9
    This comparison between a function that doesn't get affected by send() with one which does, really helped. Thanks! – Manas Bajaj Aug 10 '18 at 10:42

Some use cases for using generator and send()

Generators with send() allow:

  • remembering internal state of the execution
    • what step we are at
    • what is current status of our data
  • returning sequence of values
  • receiving sequence of inputs

Here are some use cases:

Watched attempt to follow a recipe

Let us have a recipe, which expects predefined set of inputs in some order.

We may:

  • create a watched_attempt instance from the recipe
  • let it get some inputs
  • with each input return information about what is currently in the pot
  • with each input check, that the input is the expected one (and fail if it is not)

    def recipe():
        pot = []
        action = yield pot
        assert action == ("add", "water")
        action = yield pot
        assert action == ("add", "salt")
        action = yield pot
        assert action == ("boil", "water")
        action = yield pot
        assert action == ("add", "pasta")
        action = yield pot
        assert action == ("decant", "water")
        action = yield pot
        assert action == ("serve")
        pot = []
        yield pot

To use it, first create the watched_attempt instance:

>>> watched_attempt = recipe()                                                                         
>>> watched_attempt.next()                                                                                     

The call to .next() is necessary to start execution of the generator.

Returned value shows, our pot is currently empty.

Now do few actions following what the recipe expects:

>>> watched_attempt.send(("add", "water"))                                                                     
>>> watched_attempt.send(("add", "salt"))                                                                      
['water', 'salt']                                                                                      
>>> watched_attempt.send(("boil", "water"))                                                                    
['water', 'salt']                                                                                      
>>> watched_attempt.send(("add", "pasta"))                                                                     
['water', 'salt', 'pasta']                                                                             
>>> watched_attempt.send(("decant", "water"))                                                                  
['salt', 'pasta']                                                                                      
>>> watched_attempt.send(("serve"))                                                                            

As we see, the pot is finally empty.

In case, one would not follow the recipe, it would fail (what could be desired outcome of watched attempt to cook something - just learning we did not pay enough attention when given instructions.

>>> watched_attempt = running.recipe()                                                                         
>>> watched_attempt.next()                                                                                     
>>> watched_attempt.send(("add", "water"))                                                                     
>>> watched_attempt.send(("add", "pasta")) 

AssertionError                            Traceback (most recent call last)
<ipython-input-21-facdf014fe8e> in <module>()
----> 1 watched_attempt.send(("add", "pasta"))

/home/javl/sandbox/stack/send/running.py in recipe()
     30     action = yield pot
---> 31     assert action == ("add", "salt")
     32     pot.append(action[1])


Notice, that:

  • there is linear sequence of expected steps
  • the steps may differ (some are removing, some are adding to the pot)
  • we manage to do all that by a functions/generator - no need to use complex class or similar strutures.

Running totals

We may use the generator to keep track of running total of values sent to it.

Any time we add a number, count of inputs and total sum is returned (valid for the moment previous input was send into it).

from collections import namedtuple

RunningTotal = namedtuple("RunningTotal", ["n", "total"])

def runningtotals(n=0, total=0):
    while True:
        delta = yield RunningTotal(n, total)
        if delta:
            n += 1
            total += delta

if __name__ == "__main__":
    nums = [9, 8, None, 3, 4, 2, 1]

    bookeeper = runningtotals()
    print bookeeper.next()
    for num in nums:
        print num, bookeeper.send(num)

The output would look like:

RunningTotal(n=0, total=0)
9 RunningTotal(n=1, total=9)
8 RunningTotal(n=2, total=17)
None RunningTotal(n=2, total=17)
3 RunningTotal(n=3, total=20)
4 RunningTotal(n=4, total=24)
2 RunningTotal(n=5, total=26)
1 RunningTotal(n=6, total=27)
  • This is useful. It deserves more upvotes – Angel Salazar May 9 at 1:07

The send method implements coroutines.

If you haven't encountered Coroutines they are tricky to wrap your head around because they change the way a program flows. You can read a good tutorial for more details.


The send() method controls what the value to the left of the yield expression will be.

To understand how yield differs and what value it holds, lets first quickly refresh on the order python code is evaluated.

Section 6.15 Evaluation order

Python evaluates expressions from left to right. Notice that while evaluating an assignment, the right-hand side is evaluated before the left-hand side.

So an expression a = b the right hand side is evaluated first.

As the following demonstrates that a[p('left')] = p('right') the right hand side is evaluated first.

>>> def p(side):
...     print(side)
...     return 0
>>> a[p('left')] = p('right')
>>> [p('left'), p('right')]
[0, 0]

What does yield do?, yield, suspends execution of the function and returns to the caller, and resumes execution at the same place it left off prior to suspending.

Where exactly is execution suspended? You might have guessed it already... the execution is suspended between the right and left side of the yield expression. So new_val = yield old_val the execution is halted at the = sign, and the value on the right (which is before suspending, and is also the value returned to the caller) may be something different then the value on the left (which is the value being assigned after resuming execution).

yield yields 2 values, one to the right and another to the left.

How do you control the value to the left hand side of the yield expression? via the .send() method.

6.2.9. Yield expressions

The value of the yield expression after resuming depends on the method which resumed the execution. If __next__() is used (typically via either a for or the next() builtin) then the result is None. Otherwise, if send() is used, then the result will be the value passed in to that method.

  • 1
    this answer deserves more upvotes – aafulei Apr 11 at 8:19

These confused me too. Here is an example I made when trying to set up a generator which yields and accepts signals in alternating order (yield, accept, yield, accept)...

def echo_sound():

    thing_to_say = '<Sound of wind on cliffs>'
    while True:
        thing_to_say = (yield thing_to_say)
        thing_to_say = '...'.join([thing_to_say]+[thing_to_say[-6:]]*2)
        yield None  # This is the return value of send.

gen = echo_sound()

print 'You are lost in the wilderness, calling for help.'

print '------'
in_message = gen.next()
print 'You hear: "{}"'.format(in_message)
out_message = 'Hello!'
print 'You yell "{}"'.format(out_message)

print '------'
in_message = gen.next()
print 'You hear: "{}"'.format(in_message)
out_message = 'Is anybody out there?'
print 'You yell "{}"'.format(out_message)

print '------'
in_message = gen.next()
print 'You hear: "{}"'.format(in_message)
out_message = 'Help!'
print 'You yell "{}"'.format(out_message)

The output is:

You are lost in the wilderness, calling for help.
You hear: "<Sound of wind on cliffs>"
You yell "Hello!"
You hear: "Hello!...Hello!...Hello!"
You yell "Is anybody out there?"
You hear: "Is anybody out there?...there?...there?"
You yell "Help!"

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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