I am learning to write a backend server that can handle thousands of connections.

I take a look on some sample code, but find it is still writing in sync logic.

For example: (take from http://www.tornadoweb.org/en/stable/gen.html)

def get(self):
    http_client = AsyncHTTPClient()
    response1, response2 = yield [http_client.fetch(url1), http_client.fetch(url2)]
    print(response1.body, response2.body)

It is obvious that the print statement couldn't execute before getting the response of the two fetches, or else it will throw exception due to accessing not exist data.

Therefore, it must have a block between the last two lines, but, block, isn't tornado is highlight for non-block, async, event-driven... and then, could handle thousands of connections?


Yes, tornado is asynchronous. The example you're showing is a coroutine; it's actually non-blocking, and releases control back to the tornado event loop at the yield call. Control only returns back to the get function when both http_client.fetch calls have actually completed.

These two examples are actually functionally equivalent in tornado:

class AsyncHandler(RequestHandler):
    def get(self):
        http_client = AsyncHTTPClient()

    def on_fetch(self, response):

And a coroutine version:

class GenAsyncHandler(RequestHandler):
    def get(self):
        http_client = AsyncHTTPClient()
        response = yield http_client.fetch("http://example.com")

Coroutines allow you to write asynchronous code that looks synchronous, which is more readable. When the above code hits the yield, get suspends and yields the Future object returned by http_client.fetch to the gen.coroutine decorator. The gen.coroutine decorator has magic in it that schedules the result of the Future returned by the fetch call to be passed back into get once its ready.

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  • I am just making a Q&A style question... Please have a look on my answer. – Eugene Sep 1 '14 at 7:24


It is very likely to confuse with the two different pattern to use yield and coroutine between long running jobs and slow IO operations. I have just make a critical mistake on that.

  • In long running jobs

    1. The next() method of its generator is repeatedly called, and do a unit of work every time.
    2. If have more than one coroutine running, the scheduler will call each next() method one by one, so it share CPU time between the jobs. So it is cooperative between the jobs, therefore called coroutine.
  • In slow IO operations

    1. The next() method is called only once for each yield point.
    2. Once yield from the point doing IO operation, the IO operation has delegate to OS kernel. The scheduler will add a callback when IO operation has complete, which will call the next() method.
    3. And now it is a question for scheduler when to call the next() method. This is powered by OS level async feature, like epoll, IOCP to notiy scheduler when IO has complete.
    4. So the whole flow is, running to the point making IO, than yield to hand over execution. After IO has complete, it will continue execute by call next() from the scheduler.
    5. The effects of this control flow is exactly same with callback pattern, both are
      • run to a point dong IO
      • handover the execution so the process could do other jobs
      • IO has completed, continue running.
      • The only difference is one is continue to execute on the former function, and the other continue to a new callback function.

So, in summary:

  • in long running jobs, the scheduler will call each next() method once the process is idle.

  • in slow IO operations, the next() method is called only once, when the IO operations has finished.

I think if you realize that, you will understand that use yield and coroutine actually could have the same power with callback.

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  • 1
    From the Tornado docs intro: "Tornado is a Python web framework and asynchronous networking library". While there are differences between async and non-blocking, you're a bit off here. – Cole Maclean Sep 1 '14 at 9:34
  • Tornado is both asynchronous and non-blocking. The doc page you linked to describes examples of tornado code that use callbacks and coroutines as asynchronous. Also, the piece about lightweight threads not truly making things asynchronous is a reference to gevent, not coroutines. – dano Sep 1 '14 at 14:05
  • 1
    The difference between "blocking" and "asynchronous" as described in the tornado docs is simply "does this code return before it's actually finished doing its work?" If it does, it's asynchronous. If it waits to finish its work prior to returning, it's blocking. Tornado allows you to write code in both of these styles. Now, tornado also allows you to make non-blocking I/O calls in functions that are synchronous, via coroutines, but those can easily be used in an asynchronous way (by not yielding from them). – dano Sep 1 '14 at 14:11
  • Non-blocking synchronous functions do exist, but that means something different than you're saying here. send() and recv() on a POSIX socket in non-blocking mode are synchronous in that if they return EAGAIN they do not continue working in the background (unlike Windows IOCP in which the socket calls are truly asynchronous). – Ben Darnell Sep 1 '14 at 14:17

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