You go off and do something else

Yeah of course, fire and forget. I only know how to fire and forget by using a separate process

a side effect of that is that when the response arrives, you might be busy doing something else and not tell me about it right away

Because you are only one person, you only have a single thread of execution

but you are capable of organising your available time to efficiently process the things you need to do

you use a calendar or something to manage your schedule

that's what an event loop does, it's a scheduler. It's just time management

Which you use together with async to tell it to continue executing and what, poll (tick()) for something back?

@Jimbo async is an effect of that scheduling

Okay, so I get the loop bit then, it's now this magical scheduling that I don't

The loop is what does the scheduling

specifically this bit:

timeout = getTimeUntilNextTimer();

if (haveIoToWatch()) {
    watchForIo(timeout);
} else {
    sleep(timeout);
}

timeout is "how long before the next thing I have scheduled"

i.e. things done with setTimeout() etc

Okay, so haveIoToWatch is looking at an internal array of operations that we're 'watching' for

How does the watching work, the watchForIo bit

@Jimbo epoll()/kqueue()/select() - type operations

Which are dealt with by the OS

Don't worry about how those bits work underneath for now, just trust that they do

You basically say to the OS "tell me when something interesting happens on one of these streams/fds/signal sources/whatever"

@Jimbo PHP under the hood is making operating-system calls that do this for you

PHP doesn't implement this, it's just a proxy for OS level calls

Put it this way @Jimbo: I don't even really know how it works, because I don't write operating systems. It is simply not relevant to an application developer.

@DaveRandom So PHP can watch on three different streams, I'm guessing that kqueue is the best right. How do we say from PHP land - this operation is going to be executed over this stream?

It's on the same kind of level as how hardware drivers work: it just doesn't matter, you have to trust that they do

@Jimbo tbh you don't even need to worry about it at that level. PHP only exposes select() to userland (via stream_select()), other extensions like ev/uv use epoll()/kqueue() under the hood when they are available, but they are using cross-OS abstraction libs, so even the PHP extension code doesn't know what mechanism is being used underneath

it doesn't really matter

you are going too far down the rabbit hole for the purposes of this talk

Windows has a completely different mechanism for dealing with that stuff, again you just don't need to worry about it

Okay I'll just trying to think from PHP land then. I still need to get, briefly, how PHP achieves this though. Let's say we have a http request. Is there a list of 'things' we can do that are async, therefore we know we can do this over stream select and not block, or something?

@Jimbo OK so it's worth getting a clear separation in your mind between "asynchronous" and "non-blocking"

asynchronous is the process of doing other stuff while you are waiting, non-blocking is just a tool that enables the process

When you mix and match the terminology (which a lot of people do, all the time) it can get really confusing really fast

...or just don't attempt to dismantle the black box, because you don't need to in order to write an application on top of it :-P

nevertheless a desire to understand is commendable

@DaveRandom Sure, but.. I need to first identify if something would be blocking. Is there a finite list available of what is? Secondly - let's say it is blocking. This means I can't use yield and everything will be dandy right

OK so going back to the letter analogy @Jimbo: sending a letter would be a blocking operation if after you had done it, they made you wait in the post office until the got the response

So saying yield allows me to continue doing what I want, until the operation has finished and the CB is executed (as in, I say, thanks, I'm going to do something with your letter back now)

Kinda noisying up #11 with this

Yeah

> So saying yield allows me to continue doing what I want, until the operation has finished and the CB is executed (as in, I say, thanks, I'm going to do something with your letter back now)

← 39 messages moved from PHP

← 1 message moved from PHP

need to go now, But I'll read this up later to give feedback about Daves suggestions…

@Jimbo yield is basically like writing something down in your calendar

It's saying "I'll come back to this when I can do something else with it"

When you send that letter:

$response = yield $postOffice->send($letter);

The yield there is basically saying "when the response arrives, put it into $response and the progress, until then you can go do something else"

Okay, so we write that line of code, what confuses me is how that's picked up and stored (?) in "things to process" or "watchForIoFrom"

Why isn't it $eventLoop->addThingToBeProcessed(yield $postOffice->send($letter)); or something

@Jimbo because yield is more like return

Think about how a regular generator works

moment

3v4l.org/OYbBZ

So in that code, $i is being echoed, but the generator doesn't know that

Yep, same as return there right, except.. something about not storing everything in memory or something?

The function is returning a value without ending execution, it's just pausing execution

But it is the caller of the function that needs to worry about what to do with the value that is emitted

So you don't need to do this:

because it is the event loop that is calling the generator

Okay, so the event loop is calling gen(). gen() yields. I get that bit so far..

@Jimbo Write a coroutine and use debug_print_backtrace() to see who's calling the coroutine.

@Jimbo OK, now consider this code (moment)

3v4l.org/tZEVn

So by using Generator::send(), the caller is able to send a value back in to the generator

@Jimbo Right, Coroutine then calls onResolve on the returned promise. To resolve the promise, there will be event handler form the loop that will be called and finally resolve the Deferred this promise is linked to. That then calls all onResolve callbacks and continues the coroutine.

brb 5 min

OK right

So do you follow what Generator::send() is doing @Jimbo?

@DaveRandom Mhmm, no. I'm still messing with it

@Jimbo have you ever written a custom Iterator implementation?

Nah

damn

I'm guessing this is a prerequisite? :P

No but if you have a good understanding of how Iterator works it might be easier to understand what Generator::send() does

at the end of the day, generators are just syntactic sugar for iterators

(although send() is unique to generators, you could easily implement it manually with an iterator)

OK leaving that aside for a moment, do you understand what that pseudo-code loop is doing and why it does it like that, in that order?

Because that is a pre-requisite to understanding how generators work in the context of async

Okay one sec, maybe

So..

remember that generators are not required in order to use an event loop, they are just sugar

It makes the output iteratable ?

the output of the for loop

?

I don't get the send bit though

Maybe that's completely bollocks

Is $i += yield $i; really the simplest example?

No the loop has no "output" as such, it's at a much lower level than the generators

forget about the generators for now, just pretend it doesn't exist

lol

Okay

The loop itself is just invoking callbacks

I have an idea

do you have paid github?

in fact fuck it

give me a minute

i thought id find sexy pictures of both of you here

how disappointing

You have a github collab invite @Jimbo

I'm in

k, give me 10 mins

@DaveRandom Need a private repo?

No I just made it public

Also it seems github have sorted their shit out and I now have a working paid account again anyway

plus I use bitbucket for private stuff a lot anyway

I think GitHub is unlimited private repos now anyway, right?

yeh, but when they made that change I had a disagreement with them over my account (they screwed up the billing when they made the change)

no big deal, but I just didn't have private repos for a while

hadn't checked for ages

I have them for free anyway :D

oh maybe I do then

not check whether they have actually billed me :-P

(Because student) :P

incoherent muttering about bloody students

Oh, and once I'm no student anymore, I'll ask them to apply my 6 months from the security bug bounty which I haven't received yet, as I always had the student membership. :D

Do I need to check anything out or something?

OK @Jimbo clone that and dissect it

That is a very very simple (and deliberately inefficient for simplicity) event loop

it just does timers, it doesn't do I/O, we'll move on to that when you have looked at the it

You will notice, in particular, that Loop::run() has the exact same structure as that pseudo-code loop

Repo link for anyone else who is interested

brb 10 mins @Jimbo

Okay I'm just checking it out now

the main thing to note is that the code doesn't actually do anything until you call Loop::run() @Jimbo, and Loop::run() blocks until everything has executed. So that effectively becomes the entry point of the program itself.

before that point, all you are doing is registering things that will happen at some point in the future.

The I/O stuff can be bolted on without modifying any of that code apart from run()

which I am doing now

Okay, so.. the loop is calculating as time goes on whether or not something needs to be executed

So, scheduling

Yes, exactly. It's just managing when things need to happen.

The only difference between that and one that manages I/O as well is that at the point where usleep() is, it will instead wait for something to happen on one (or more) of the registered streams

But if it waits, it blocks?

Or does it just poll it

Well "polling" is waiting/blocking

It's waiting until there is something to do

I understood polling in this case would be if (stream has something) then use it else continue

Well yes that does describe a poll

but in this case, we know there is nothing else useful to do until either there is some activity on a stream or the timeout expires

so we block until one of those things happens

So checking for activity on a stream is okay?

Even if we wait and block everyone else?

Why don't we just check, if nothing, continue then come back to it afterwards and try again?

It's not a case of blocking everyone else, we know that there is nothing else to do

Ah, that's only because we've specified in this case 1000, 2000 etc

right?

yes, we calculated the next time we would need to do something

When you make a http request, you don't state how long it'll take...

wait a minute, let me finish writing this

If you push it could you do it in another branch so I can see the progression?

@Jimbo you can just diff the commits...?

Tsch, fine

:-P

@DaveRandom Have fun turning that into a blog series :P

It should be, but from the mind of a retard <me>

let's see how successful it is first :-P

@Jimbo The difference is that it's the scheduler that blocks once for all streams, not every stream operation blocking.

I don't understand that sentence :P Try to be less, technically concise? :D

And the stream_select will stop blocking once something on any stream happens, not on one stream.

Ah, there are multiple streams...

I didn't get this

There can be

Oh wait, yeah I did. So there's one stream per operation?

There can be, yes.

@Jimbo A "stream" is a file descriptor or a network socket

There's no other types?

So for each open file or open network socket in the application, you register a "watcher"

@Jimbo There might be, but none that you need to worry about right now (read: none that I have ever done anything with ever)

So the example we have right now is just executing something that immediately runs. Except the running of it is blocking. So when we actually run something, we need to... "put it into a stream" (for lack of a better understanding) then watch it for it's response?

Or something something

Well it depends what the application is doing. If the application only needs to do something every second (e.g. updating a clock in a GUI) then you don't need to do anything else at all.

The point of the event loop is the entire application is running within it

I'm gonna go grab a sandwich and some pills, but I get what we're doing right now, not how we'll register things that need to be done but take an indeterminate amount of time using these stream things

I should be done with this in a few minutes, I'm just debugging it

pushed @Jimbo (and @kelunik if you are interested)

Something notable about it now is that even with that super-simple example we are starting to see callback hell with the stream processing code, even though it isn't really even doing anything

so next we'll look at a few ways to rewrite the example code. We don't need to touch the event loop for a while now, possibly never again

obviously the event loop leaves a lot to be desired - it's not very efficient because it iterates potentially very large arrays a lot of times, and it currently has no way to cancel a setTimeout(). Those are ways in which it can be improved, but that will make the code a lot more complex and it won't fundamentally change the way it works, so we're ignoring that stuff for now because we aren't trying to build a real-world application.

@Jimbo @kelunik I'm about to rewrite history, sorry :-/

OK done, force pull if you had already pulled

@DaveRandom Any pull will force pull.

will it? I didn't think that was true, you'll get a merge conflict?

@DaveRandom Only if you have changes I think.

meh, would have to test

I just modified the example so that it used several remote servers to increase the chances that things will happen in a different order to the way they were written, to demonstrate that it actually is async

when you send google.com 5 requests in a row, they tend to respond in the same order

Ok am back

Do we monitor all streams at once?

Yes

Ah nice, and activity on any triggers a callback?

You only ever have one loop instance (it is effectively the runtime) and you register all streams with that loop

@Jimbo yes

OK so there are now 2 more commits, but don't look at them until you are ready

or well, let me know when you are ready to move on and I will explain them first

Okay so

Only once the stream is writeable and the callback is being executed for it do we add a read one in

That's where the callback hell is starting?

The TCP client I just accept is 'magic' in that it can do async

Okay I think I get it

@Jimbo "callback hell" is a result of the fact that you can't register the next callback until the previous one completes

so here: github.com/DaveRandom/JimboLoop/commit/…

we couldn't register that onReadable() callback until we'd done the write

then if you have some other action to perform after the read, you'd end up with another nested layer, and the code swiftly become impossible to follow

Yep exactly

I saw that, okay

@Jimbo The TCP client is just a socket, nothing particularly special about it

Except it has this magic flag that makes it async

that tcp_client() function is only there to remove boilerplate

@Jimbo OK so how well do you understand TCP?

Hello would you like to hear a TCP joke? Also - no, nothing.

:-P

But I guess that's not necessary for this example

@Jimbo it's necessary to understand what the ASYNC_CONNECT flag is doing

and it's not particularly difficult

So when a TCP connection is being initiated, the client sends a SYN (synchronisation) packet to the server

the server then responds with a SYN/ACK (synchronisation/acknowledgment) packet

when you call stream_socket_client() without the ASYNC_CONNECT flag, it blocks until it receives the response packet from the server

when you pass that flag, the client just sends the SYN packet and then returns immediately

after that, when the client's OS has received the SYN/ACK from the server, the socket will become writable

hence the reason that code creates the client socket, then watches for writability

Ah, I see

Pretty simple

OK so if you look at the next 2 commits, the first one is just creating some function primitives. We do this because the loop is effectively the runtime, it doesn't make sense to have more than one instance, and it needs to be globally accessible.

Okay so you expose them globally yep

The second commit is just rewriting the 2nd example to use those primitives

Do we have to do this?

@Jimbo no, you can still DI everything if you want, but it makes the code messier and is actually unnecessary

Ok

I know it goes against everything that one holds dear in terms of good OOP practice, but when you are writing an application you shouldn't be thinking about how the loop works

So that custom DB implementation that (was it PeeHaa who wrote it) works async, that's just calling MySQL over TCP?

You mean amp/mysql?

Yep

Or even in this implementation

That's how we could code it?

That's a mysql protocol implementation written in PHP

it's a layer higher up than the loop

OK so I added another example @Jimbo which is just another way of writing that code without the nested callbacks

Nice, I get it

It still hasn't fundamentally changed, it's just restructured to be a little bit more readable, but it's still not great

So next we're going to introduce promises, which will initially look like a step backwards

Totally unrelated, but I maybe just found a way to pass data back into the running event loop via SI_QUEUE, perhaps

Supported in PHP as of 5.3

Ah, but enabling PCNTL is slow because of the polling, nvm

OK @Jimbo so I added a promise/promisor example. That is going to look like a shit mess at first, and it is not going to look like progress, but it's a means to an end

@Jimbo signalling is also doable, I've ignored that for now because it would make the loop quite a lot more complex

It's also not that useful most of the time, you generally only use that for administrative operations (telling your program to exit/restart/reload config etc)

yep yep, it'd be a bit of a hack really

If you want to pass data around, you use sockets

This can be a unix domain socket though, it doesn't need to hit the network

You can also use stdio for a child process (this is effectively a file descriptor, and the loop handles it in the same way)

I'm going home but I will be back in a bit

I'm certain you will have a lot of questions about the promises thing because it look confusing and horrid

bbiab

Well, yeah. Brain deadded

You just wrote a deferred promise implementation and broke my brain

I think we should take a break for now maybe? :D

@Jimbo re signals: signals will just interrupt the select(2) syscall and we can then do a simple signal dispatch after the stream_select() returns, i.e. we just pcntl_signal_dispatch(), which will call our registered callbacks and we are done.

Okay so back to streams

Let's say we've done 2 requests. We don't get to the point where we check the stream and then block, do we?

Or we do... and we block because we're checking both streams at once

And what if only one stream returns, we just execute the callback for the first one, and then re-go-around and do the second one?

Please say this is the case, because if so I think my understanding upped a bit. If not, fuck

@Jimbo Then we continue the while loop and stream_select on both streams again

No because the first stream will be done

Unless the first one is finished and unregistered

Excellent :)

Okay I get it, so it's okay to block because we're blocking on everything

There's nothing else that needs to happen while we wait for anything to come back

Hmm, actually... we can't subscribe to new streams during this time

If we wouldn't block there, we'd run at 100% CPU.

Ah, and this is blocking IO

amiright

@Jimbo Hm?

@Jimbo To subscribe to a new stream, something has to subscribe to it. As nothing is ready to execute, there can't be anything that wants to subscribe to a new stream

Okay so stream_select, while it's waiting for something to come back on a stream, we want to do something else... like, add a new stream to be polled

Okay I'm jumping too far ahead with dynamically added events

@Jimbo Where does the new stream come from?

Client wants to subscribe to result of stream

@Jimbo When some code is currently running, we're not currently blocking in stream_select

If it's a timer, then stream_select might have timed out and the timer is executed and can subscribe. If it's a new connection, stream_select will return and execute the readable event handler of the server socket.

So at one point it was blocking, and that's the time that I'm talking about for when we can't do anything else

But, I think I get it

It's okay because there's nothing else to do, or something..

@Jimbo That or something indicates we're not quite there yet :D

@kelunik Say we have two streams. One's TCP, one's a file descriptor

The file descriptor - we have to wait until we get something back. But from what I remember from our discussions today, the TCP one returns instantly

w/ the async flag

I have a question revolving somewhere around that

Because I get the file descriptor bit - we block on that stream

@Jimbo Usually you shouldn't do that, because it blocks everything.

@Jimbo local files are, for the purposes of this exercise, instant

But if we're blocking by using stream select, what's the point of using that and not just a file get contents or something? Just so we're to polling?

Is it just so we have a file watcher for change?

real non-blocking filesystem I/O is a huge pita, but that is because of OS-level limitations, nothing we can do about that

@Jimbo the default implementation of amp/file uses blocking I/O

@DaveRandom Which is what we've got here right?

libuv has some non-blocking implementations which are used if available (I think?)

@DaveRandom Yes. And we have a parallel driver to avoid blocking even without uv.

@Jimbo yes, like I said for the purposes of this exercise, file-system I/O is instant

Okay

As for network... we have the async thing. If it returns instantly...

We don't block with stream select?

filesystem stuff is a rabbit hole you really don't want to start down...

@Jimbo A file descriptor, from the point of view of select(), is always readable and always writable

i.e. select() will always return instantly if you give it a local file descriptor in any of the fd sets

It's still a valid thing to do, it's just that OS lies to you a bit

not much though, tbh especially if you have SSDs it may as well actually be instant

@Jimbo you know how I was saying people mix up "async" and "non-blocking" a lot, as if they are interchangeable?

STREAM_CLIENT_ASYNC_CONNECT is a good example of that

it would be more accurately named STREAM_CLIENT_NONBLOCKING_CONNECT

If it returns instantly though, how do we know the difference between an instant return and 'we actually have the data now'?

To invoke the callback with

@Jimbo that's why you watch for writability

when the connection is fully established, the socket becomes writable

Ah, I forgot we watch for both read and write

Oh okay

yes, in general you watch a socket for readability constantly, but you only watch it for writability when you actually need to

that's because, fairly obviously, you need to be prepared to recieve data at any time because you have no control over that, but you know when you are sending

And because this is a stream we're dealing with, and we get streaming data, we apply the callback every time the data is written on it?

Well the callback is only a notification handler, effectively. So in the case of onReadable() the callback is invoked every time there is some data available to read from the socket

you'll notice that the loop itself never performs any actual read/write operations

it only watches them for the requested status

It's the responsibility of the consuming code to deal with actually performing open/close/read/write operations

brb 5 min

OK are you ready to move on to generators yet @Jimbo? :-P

Lol

Right now I'm looking over my slides for my talk for tomorrow, and removing all the stuff about IPC a buffer filling for event loops because it's nothing like that in PHP

Well, it is, sort of, but very abstract

The thing to remember is the word "event", i.e. only doing something when there is something to do.

Like, if you go back to example #1, if you told those callbacks to run after 1,2,3,4,5 milliseconds, they wouldn't actually all run at the exact times you specified, because they will most likely take longer than 1ms to execute

Of course

Whenever you see a timeout in a single-threaded async application, it's more an expression of desire than a rule, you are saying "I'd like to run this as close as possible to, but not before, this timeout expires"

In reality though that doesn't matter for real world applications, things will generally run within a few milliseconds of precision