In this lesson we're going to look at subscriptions. Subscriptions are probably the most complicated part of writing agents, so there's a fair bit to cover. Before we get into the nitty-gritty details, we'll give a brief overview of Gall's subscription mechanics.
The basic unit of subscriptions is the path. An agent will typically define a number of subscription paths in its on-watch
arm, and other agents (local or remote) can subscribe to those paths. The agent will then send out updates called %fact
s on one or more of its paths, and all subscribers of those paths will receive them. An agent cannot send out updates to specific subscribers, it can only target its paths. An agent can kick subscribers from its paths, and subscribers can unsubscribe from any paths.
The subscription paths an agent defines can be simple and fixed like /foo/bar/baz
. They can also be dynamic, containing data of a particular atom aura encoded in certain elements of the path. These paths can therefore be as simple or complex as you need for your particular application.
Note it's not strictly necessary to define subscription paths explicitly. As long as the arm doesn't crash, the subscription will succeed. In practice, however, it's nearly always appropriate to define them explicitly and crash on unrecognized paths.
For a deeper explanation of subscription mechanics in Arvo, you can refer to Arvo's Subscriptions section.
Incoming subscriptions
Subscription requests from other entities arrive in your agent's on-watch
arm. The on-watch
arm takes the path
to which they're subscribing, and produces a (quip card _this)
:
++ on-watch|= =path^- (quip card _this)...
Your agent's subscription paths would be defined in this arm, typically in a wutlus (?+
) expression or similar:
?+ path (on-watch:def path)[%updates ~]............[%blah %blah ~]............[%foo @ ~]=/ when=@da (slav %da i.t.path)............[%bar %baz *]?+ t.t.path (on-watch:def path)~ .....[%abc %def ~] .....[%blah ~] .....====
Subscription paths can be simple and fixed like the first two examples above: /updates
and /blah/blah
. They can also contain "wildcard" elements, with an atom of a particular aura encoded in an element of the path
, as in the [%foo @ ~]
example. The type pattern matcher is quite limited, so we just specify such variable elements as @
, and then decode them with something like (slav %da i.t.path)
(for a @da
), as in the example. The incoming path
in this example would look like /foo/~2021.11.14..13.30.39..6b17
. For more information on decoding atoms in strings, see the Strings Guide.
In the last case of [%bar %baz *]
, we're allowing a variable number of elements in the path. First we check it's /bar/baz/...something...
, and then we check what the "something" is in another wutlus expression and handle it appropriately. In this case, it could be /bar/baz
, /bar/baz/abc/def
, or /bar/baz/blah
. You could of course also have "wildcard" elements here too, so there's not really a limit to the complexity of your subscription paths, or the data that might be encoded therein.
Permissions can be checked as described in the previous lesson, comparing the source @p
of the request in src.bowl
to our.bowl
or any other logic you find appropriate.
If a permission check fails, the path is not valid, or any other reason you want to reject the subscription request, your agent can simply crash. The behavior here is the same as with on-poke
- Gall will send a %watch-ack
card in response, which is either an ack (positive acknowledgement) or a nack (negative acknowledgement). The (unit tang)
in the %watch-ack
will be null if processing succeeded, and non-null if it crashed, with a stack trace in the tang
. Like with poke-ack
s, you don't need to explicitly send a %watch-ack
- Gall will do it automatically.
As well as sending a %watch-ack
, Gall will also record the subscription in the sup
field of the bowl
, if it succeeded. Then, when you send updates out to subscribers of the path
in question, the new subscriber will begin receiving them as well.
Updates to subscribers would usually be sent from other arms, but there's one special case for on-watch
which is very useful. Normally updates can only be sent to all subscribers of a particular path - you can't target a specific subscriber. There's one exception to this: In on-watch
, when there's a new subscription, you can send a %fact
back with an empty (list path)
, and it'll only go to the new subscriber. This is most useful when you want to give the subscriber some initial state, which you otherwise couldn't do without sending it to everyone. It might look something like this:
:_ this:~ [%give %fact ~ %todo-update !>(`update:todo`initial+tasks)]==
Sending updates to subscribers
Once your agent has subscribers, it's easy to send them out updates. All you need to do is produce card
s with %fact
s in them:
:_ this:~ [%give %fact ~[/some/path /another/path] %some-mark !>('some data')][%give %fact ~[/some/path] %some-mark !>('more data')]....==
The (list path)
in the %fact
specifies which subscription path
s the %fact
should be sent on. All subscribers of all path
s specified will receive the %fact
. Any agent arm which produces a (quip card _this)
can send %fact
s to subscribers. Most often they will be produced in the on-poke
arm, since new data will often be added in poke
s.
Kicking subscribers
To kick a subscriber, you just send a %kick
card
:
[%give %kick ~[/some/path] `~sampel-palnet]
The (list path)
specifies which subscription path
s the ship should be kicked from, and the (unit ship)
specifies which ship to kick. The (unit ship)
can also be null, like so:
[%give %kick ~[/some/path] ~]
In this case, all subscribers to the specified path
s will be kicked.
Note that %kick
s are not exclusively sent by the agent itself - Gall itself can also kick subscribers under certain network conditions. Because of this, %kick
s are not assumed to be intentional, and the usual behavior is for a kicked agent to try and resubscribe. Therefore, if you want to disallow a particular subscriber, your agent's on-watch
arm should reject further subscription requests from them - your agent should not just %kick
them and call it a day.
Outgoing subscriptions
Now that we've covered incoming subscriptions, we'll look at the other side of it: Subscribing to other agents. This is done by %pass
ing the target agent a %watch
task in a card
:
[%pass /some/wire %agent [~some-ship %some-agent] %watch /some/path]
If your agent's subscription request is successful, updates will come in to your agent's on-agent
arm on the wire
specified (/some/wire
in this example). The wire
can be anything you like - its purpose is for your agent to figure out which subscription the updates came from. The [ship term]
pair specifies the ship and agent you're trying to subscribe to, and the final path
(/some/path
in this example) is the path you want to subscribe to - a path
the target agent has defined in its on-watch
arm.
Gall will deliver the card
to the target agent and call that agent's on-watch
arm, which will process the request as described above, accept or reject it, and send back either a positive or negative %watch-ack
. The %watch-ack
will come back in to your agent's on-agent
arm in a sign
, along with the wire
you specified (/some/wire
in this example). Recall in the lesson on pokes, the on-agent
arm starts with:
++ on-agent|= [=wire =sign:agent:gall]^- (quip card _this).....
The sign
will be of the following format:
[%watch-ack p=(unit tang)]
How you want to handle the %watch-ack
really depends on the particular agent. In the simplest case, you can just pass it to the on-agent
arm of default-agent
, which will just accept it and do nothing apart from printing the error in the %watch-ack
tang
if it's a nack. You shouldn't have your agent crash on a %watch-ack
- even if it's a nack your agent should process it successfully. If you wanted to apply some additional logic on receipt of the %watch-ack
, you'd typically first test the wire
, then test whether it's a %watch-ack
, then test whether it's an ack or a nack and do whatever's appropriate:
++ on-agent|= [=wire =sign:agent:gall]^- (quip card _this)?+ wire (on-agent:def wire sign)[%expected %wire ~]?+ -.sign (on-agent:def wire sign)%watch-ack?~ p.sign...(do something if ack)......(do something if nack).........
The on-agent
arm produces a (quip card _this)
, so you can produce new card
s and update your agent's state, as appropriate.
One further thing to note with subscriptions is that you can subscribe multiple times to the same path
on the same ship and agent, as long as the wire
is unique. If the ship, agent, path
and wire
are all the same as an existing subscription, Gall will not allow the request to be sent, and instead fail with an error message fed into the on-fail
arm of your agent.
Receiving updates
Assuming the %watch
succeeded, your agent will now begin receiving any %fact
s the other agent publishes on the path
to which you've subscribed. These %fact
s will also come in to your agent's on-agent
arm in a sign
, just like the initial %watch-ack
. The %fact
sign
will have the following format:
[%fact =cage]
You would typically handle such %fact
s in the following manner: Test the wire
, test whether the sign
is a %fact
, test the mark
in the cage
, extract the data from the vase
in the cage
, and apply your logic. For example:
++ on-agent|= [=wire =sign:agent:gall]^- (quip card _this)?+ wire (on-agent:def wire sign)[%expected %wire ~]?+ -.sign (on-agent:def wire sign)%fact?+ p.cage.sign (on-agent:def wire sign)%expected-mark=/ foo !<(expected-type q.cage.sign)...........
Note that Gall will not allow sign
s to come into on-agent
unsolicited, so you don't necessarily need to include permission logic in this arm.
The on-agent
arm produces a (quip card _this)
, so you can produce new card
s and update your agent's state, as appropriate.
Getting kicked
For whatever reason, the agent you're %watch
ing might want to kick your agent from a path
to which it's subscribed, ending your subscription and ceasing to send your agent %fact
s. To do this, it will send your agent a %kick
card as described above. The %kick
will come in to your agent's on-agent
arm in a sign
, like %watch-ack
s and %fact
s do. The %kick
sign
will have the following format:
[%kick ~]
Since the %kick
itself contains no information, you'll need to consider the wire
it comes in on to know what it pertains to. As explained previously, %kick
s aren't always intentional - sometimes Gall will kick subscribers due to network issues. Your on-agent
arm therefore has no way to know whether the other agent actually intended to kick it. This means your agent should almost always try to resubscribe if it gets kicked. Then, if the resubscribe %watch
request is rejected with a negative %watch-ack
, you can conclude that it was intentional and give up. The logic would look something like this:
++ on-agent|= [=wire =sign:agent:gall]^- (quip card _this)?+ wire (on-agent:def wire sign)[%some %wire ~]?+ -.sign (on-agent:def wire sign)%kick:_ this:~ [%pass /some/wire %agent [src.bowl dap.bowl] %watch /some/path]==.......
Leaving a subscription
Eventually you may wish to unsubscribe from a path
in another agent and stop receiving updates. This is done by %pass
ing a %leave
task to the agent in question:
[%pass /some/wire %agent [~some-ship %some-agent] %leave ~]
The subscription to be ended is determined by the combination of the wire
, ship and agent, so the %leave
task itself always just has ~
at the end.
Example
Here we're going to give a pretty well fleshed out example. It will demonstrate both inbound and outbound subscriptions, most of the concepts we've discussed here, as well as some from the previous lesson - /sur
files, mark
files, and permission checks.
In previous lessons we've only dealt with things on a local ship - this example will demonstrate messages being sent over the network.
The example will be composed of two separate agents - a publisher called /app/todo.hoon
and a subscriber called /app/todo-watcher.hoon
, which will live on separate ships. It will be a very rudimentary To-Do app - to-do tasks will be poked into the publisher and sent out to the subscriber as %fact
s, which will just print them to the dojo. It will have its types defined in /sur/todo.hoon
, and it will have a couple of mark
files for pokes and updates: /mar/todo/action.hoon
and /mar/todo/update.hoon
.
Before we get into trying it out, we'll first walk through the /sur
file, mark files, and each agent.
Types and marks
/sur/todo.hoon
Click to expand
|%+$ id @+$ name @t+$ task [=name done=?]+$ tasks (map id task)+$ who @p+$ friends (set who)+$ action$% [%add =name][%del =id][%toggle =id][%rename =id =name][%allow =who][%kick =who]==+$ update$% [%add =id =name][%del =id][%toggle =id][%rename =id =name][%initial =tasks]==--
This file defines most of the types for the agents. The list of to-do tasks will be stored in the state of the publisher agent as the tasks
type, a (map id task)
, where a task
is a [=name done=?]
. The set of ships allowed to subscribe will be stored in friends
, a (set @p)
, also in the publisher's state. After that, there are the head-tagged unions of accepted poke action
s and update
s for subscribers.
/mar/todo/action.hoon
Click to expand
/- todo|_ =action:todo++ grab|%++ noun action:todo--++ grow|%++ noun action--++ grad %noun--
This is a very simple mark file for the action
type.
/mar/todo/update.hoon
Click to expand
/- todo|_ =update:todo++ grab|%++ noun update:todo--++ grow|%++ noun update--++ grad %noun--
This is a very simple mark file for the update
type.
Publisher
/app/todo.hoon
Click to expand
/- todo/+ default-agent, dbug|%+$ versioned-state$% state-0==+$ state-0 [%0 =friends:todo =tasks:todo]+$ card card:agent:gall--%- agent:dbug=| state-0=* state -^- agent:gall|_ =bowl:gall+* this .def ~(. (default-agent this %.n) bowl)::++ on-init^- (quip card _this)`this::++ on-save^- vase!>(state)::++ on-load|= old-state=vase^- (quip card _this)=/ old !<(versioned-state old-state)?- -.old%0 `this(state old)==::++ on-poke|= [=mark =vase]^- (quip card _this)|^?> =(src.bowl our.bowl)?+ mark (on-poke:def mark vase)%todo-action=^ cards state(handle-poke !<(action:todo vase))[cards this]==++ handle-poke|= =action:todo^- (quip card _state)?- -.action%add?: (~(has by tasks) now.bowl)$(now.bowl (add now.bowl ~s0..0001)):_ state(tasks (~(put by tasks) now.bowl [name.action %.n])):~ :* %give %fact ~[/updates] %todo-update!>(`update:todo`[%add now.bowl name.action])====::%del:_ state(tasks (~(del by tasks) id.action)):~ :* %give %fact ~[/updates] %todo-update!>(`update:todo`action)====::%toggle:- :~ :* %give %fact ~[/updates] %todo-update!>(`update:todo`action)== ==%= statetasks %+ ~(jab by tasks)id.action|=(=task:todo task(done !done.task))==::%rename:- :~ :* %give %fact ~[/updates] %todo-update!>(`update:todo`action)== ==%= statetasks %+ ~(jab by tasks)id.action|=(=task:todo task(name name.action))==%allow`state(friends (~(put in friends) who.action))::%kick:_ state(friends (~(del in friends) who.action)):~ [%give %kick ~[/updates] `who.action]====--::++ on-watch|= =path^- (quip card _this)?+ path (on-watch:def path)[%updates ~]?> (~(has in friends) src.bowl):_ this:~ [%give %fact ~ %todo-update !>(`update:todo`initial+tasks)]====::++ on-leave on-leave:def++ on-peek on-peek:def++ on-agent on-agent:def++ on-arvo on-arvo:def++ on-fail on-fail:def--
This is the publisher agent, todo.hoon
. The bulk of its logic is in its on-poke
arm, where it handles the various possible actions like %add
ing a task, %toggle
ing its "done" state, %rename
ing a task, and so on. It also has a couple of action
s for %allow
ing and %kick
ing subscribers.
Most of these cases both update the state of the agent, as well as producing %fact
cards to send out to subscribers with the new data.
You'll notice it only allows these pokes from the local ship, and enforces this in on-poke
with:
?> =(src.bowl our.bowl)
Additionally, you might notice the %add
case in handle-poke
begins with the following:
?: (~(has by tasks) now.bowl)$(now.bowl (add now.bowl ~s0..0001))
Back in lesson two, we mentioned that the bowl is only repopulated when there's a new Arvo event, so simultaneous messages from a local agent or web client would be processed with the same bowl. Since we're using now.bowl
for the task ID, this means multiple %add
actions could collide. To handle this case, we check if there's already an entry in the tasks
map with the current date-time, and if there is, we increase the time by a fraction of a second and try again.
Let's now look at on-watch
:
++ on-watch|= =path^- (quip card _this)?+ path (on-watch:def path)[%updates ~]?> (~(has in friends) src.bowl):_ this:~ [%give %fact ~ %todo-update !>(`update:todo`initial+tasks)]====
When on-watch
gets a subscription request, it checks whether the requesting ship is in the friends
set, and crashes if it is not. If they're in friends
, it produces a %fact
card with a null (list path)
, which means it goes only to the new subscriber. This %fact
contains the entire tasks
map as it currently exists, getting the new subscriber up to date.
Subscriber
/app/todo-watcher.hoon
/- todo/+ default-agent, dbug|%+$ versioned-state$% state-0==+$ state-0 [%0 ~]+$ card card:agent:gall--%- agent:dbug=| state-0=* state -^- agent:gall|_ =bowl:gall+* this .def ~(. (default-agent this %.n) bowl)::++ on-init^- (quip card _this)`this::++ on-save^- vase!>(state)::++ on-load|= old-state=vase^- (quip card _this)=/ old !<(versioned-state old-state)?- -.old%0 `this(state old)==::++ on-poke|= [=mark =vase]^- (quip card _this)?> =(src.bowl our.bowl)?+ mark (on-poke:def mark vase)%noun=/ action !<(?([%sub @p] [%unsub @p]) vase)?- -.action%sub:_ this:~ [%pass /todos %agent [+.action %todo] %watch /updates]==%unsub:_ this:~ [%pass /todos %agent [+.action %todo] %leave ~]======::++ on-watch on-watch:def++ on-leave on-leave:def++ on-peek on-peek:def::++ on-agent|= [=wire =sign:agent:gall]^- (quip card _this)?+ wire (on-agent:def wire sign)[%todos ~]?+ -.sign (on-agent:def wire sign)%watch-ack?~ p.sign((slog '%todo-watcher: Subscribe succeeded!' ~) `this)((slog '%todo-watcher: Subscribe failed!' ~) `this)::%kick%- (slog '%todo-watcher: Got kick, resubscribing...' ~):_ this:~ [%pass /todos %agent [src.bowl %todo] %watch /updates]==::%fact?+ p.cage.sign (on-agent:def wire sign)%todo-update~& !<(update:todo q.cage.sign)`this======::++ on-arvo on-arvo:def++ on-fail on-fail:def--
This is the subscriber agent. Since it's just for demonstrative purposes, it has no state and just prints the updates it receives. In practice it would keep the tasks
map it receives in its own state, and then update it as it receives new %fact
s.
The on-poke
arm is fairly simple - it accepts two pokes, to either [%sub ~some-ship]
or [%unsub ~some-ship]
.
The on-agent
arm will print whether a subscription request succeeded or failed, as well as printing a message when it gets kicked. When it receives a %fact
from the publisher agent, it will just print it to the terminal with a ~&
expression.
Trying it out
We're going to try this between two different ships. The first ship will be the usual fakezod. We'll add both mark
files, the /sur
file, and the todo.hoon
agent to the %base
desk of our fakezod, putting them in the following directories:
base├── app│ └── todo.hoon├── mar│ └── todo│ ├── action.hoon│ └── update.hoon└── sur└── todo.hoon
In ~zod
's dojo, we can |commit %base
, and then start the %todo
agent:
|rein %base [& %todo]
Now we need to spin up another fake ship. We'll use ~nut
in this example:
urbit -F nut
Once it's booted, we can |mount %base
and then add just the update.hoon
mark file, the /sur
file, and the todo-watcher.hoon
agent like so:
base├── app│ └── todo-watcher.hoon├── mar│ └── todo│ └── update.hoon└── sur└── todo.hoon
On ~nut
we can then |commit %base
, and start the %todo-watcher
agent:
|rein %base [& %todo-watcher]
Now, on ~nut
, let's try subscribing:
> :todo-watcher [%sub ~zod]>=%todo-watcher: Subscribe failed!
Our %todo-watcher
agent tried, but received a negative %watch-ack
from %todo
, because we haven't yet added ~nut
to the friends
set of allowed ships. Let's now remedy that on ~zod
:
> :todo &todo-action [%allow ~nut]>=
Let's also add a couple of to-do tasks, on ~zod
:
> :todo &todo-action [%add 'foo']>=> :todo &todo-action [%add 'bar']>=
If we now check its state with +dbug
, we'll see they're in the tasks
map, and ~nut
will also now be in the friends
set:
> [ %0friends={~nut}tasks{ [ p=170.141.184.505.349.079.206.522.766.950.035.095.552q=[name='foo' done=%.n]][ p=170.141.184.505.349.079.278.538.984.166.386.565.120q=[name='bar' done=%.n]]}]> :todo +dbug>=
Let's now try subscribing again on ~nut
:
> :todo-watcher [%sub ~zod]>=%todo-watcher: Subscribe succeeded![ %initialtasks{ [ p=170.141.184.505.349.079.206.522.766.950.035.095.552q=[name='foo' done=%.n]][ p=170.141.184.505.349.079.278.538.984.166.386.565.120q=[name='bar' done=%.n]]}]
As you can see, this time it's worked, and we've immediately received the initial tasks
map.
Now, let's try adding another task on ~zod
:
> :todo &todo-action [%add 'baz']>=
On ~nut
, we'll see it has received the %fact
with the new task in it:
[ %addid=170.141.184.505.349.082.779.030.192.959.445.270.528name='baz']
Let's try toggle its done state on ~zod
:
> :todo &todo-action [%toggle 170.141.184.505.349.082.779.030.192.959.445.270.528]>=
~nut
will again get the %fact
:
[ %toggleid=170.141.184.505.349.082.779.030.192.959.445.270.528]
Recall that incoming subscriptions are stored in sup.bowl
, and outgoing subscriptions are stored in wex.bowl
. Let's have a look at the incoming subscription on ~zod
:
> [ path=/updatesfrom=~nutduct=~[/gall/sys/req/~nut/todo /ames/bone/~nut/1 //ames]]> :todo +dbug [%incoming %ship ~nut]>=
On ~nut
, let's look at the outgoing subscription:
> [wire=/todos agnt=[~zod %todo] path=/updates ackd=%.y]> :todo-watcher +dbug [%outgoing %ship ~zod]>=
Now on ~zod
, let's try kicking ~nut
and removing it from our friends
set:
> :todo &todo-action [%kick ~nut]>=
On ~nut
, we'll see it got the %kick
, tried resubscribing automatically, but was rejected because ~nut
is no longer in friends
:
%todo-watcher: Got kick, resubscribing...%todo-watcher: Subscribe failed!
Summary
- Incoming subscription requests arrive in an agent's
on-watch
arm. - An agent will define various subscription
path
s in itson-watch
arm, which others can subscribe to. - Gall will automatically produce a negative
%watch-ack
ifon-watch
crashed, and a positive one if it was successful. - Incoming subscribers are recorded in the
sup
field of thebowl
. on-watch
can produce a%fact
with a null(list path)
which will go only to the new subscriber.- Updates are sent to subscribers in
%fact
cards, and contain acage
with amark
and some data in avase
. %fact
s are sent to all subscribers of the paths specified in the(list path)
.- A subscriber can be kicked from subscription paths with a
%kick
card specifying the ship in the(unit ship)
. All subscribers of the specified paths will be kicked if the(unit ship)
is null. - An outgoing subscription can be initiated with a
%watch
card. - The
%watch-ack
will come back in to the subscriber'son-agent
arm as asign
, and may be positive or negative, depending on whether the(unit tang)
is null. %kick
s will also arrive in the subscriber'son-agent
arm as asign
. Since kicks may not be intentional, the subscriber should attempt to resubscribe and only give up if the subsequent%watch-ack
is negative.%fact
s will also arrive in the subscriber'son-agent
arm.- All such
sign
s that arrive inon-agent
will also have awire
. - The
wire
for subscription updates to arrive on is specified in the initial%watch
card. - A subscriber can unsubscribe by passing a
%leave
card on the originalwire
.
Exercises
- Have a look at the Strings Guide if you're not already familiar with decoding/encoding atoms in strings.
- Try running through the example yourself, if you've not done so already.
- Try modifying
%todo-watcher
to recording the data it receives in its state, rather than simply printing it to the terminal. - If you'd like, try going back to lesson 6 (on pokes) and modifying the agents with an appropriate permission system, and also try running them on separate ships.