Introduction
A thread is like a transient gall agent. Unlike an agent, it can end and it can fail. The primary uses for threads are:
- Complex IO, like making a bunch of external API calls where each call depends on the last. Doing this in an agent significantly increases its complexity and the risk of a mishandled intermediary state corrupting permanent state. If you spin the IO out into a thread, your agent only has to make one call to the thread and receive one response.
- Testing - threads are very useful for writing complex tests for your agents.
Threads are managed by the gall agent called spider
.
Thread location
Threads live in the ted
directory of each desk. For example, in a desk named %sandbox
:
%sandbox├──app├──gen├──lib├──mar├──sur└──ted <-├──foo│ └──bar.hoon└──baz.hoon
From the dojo, ted/baz.hoon
can be run with -sandbox!baz
, and ted/foo/bar.hoon
with -sandbox!foo-bar
. Threads in the %base
desk can just be run like -foo
, but all others must have the format -desk!thread
.
NOTE: When the dojo sees the -
prefix it automatically handles creating a thread ID, composing the argument, poking the spider
gall agent and subscribing for the result. Running a thread from another context (eg. a gall agent) requires doing these things explicitly and is outside the scope of this particular tutorial.
Libraries and Structures
There are three files that matter:
/sur/spider/hoon
- this contains a few simple structures used by spider. It's not terribly useful except it imports libstrand, so you'll typically getstrand
fromspider
./lib/strand/hoon
- this contains all the main functions and structures for strands (a thread is a running strand), and you'll refer to this fairly frequently./lib/strandio/hoon
- this contains a large collection of ready-made functions for use in threads. You'll likely use many of these when you write threads, so it's very useful.
Thread definition
/sur/spider/hoon
defines a thread as:
+$ thread $-(vase _*form:(strand ,vase))
That is, a gate which takes a vase
and returns the form
of a strand
that produces a vase
. This is a little confusing and we'll look at each part in detail later. For now, note that the thread doesn't just produce a result, it actually produces a strand that takes input and produces output from which a result can be extracted. It works something like this:
This is because threads typically do a bunch of I/O so it can't just immediately produce a result and end. Instead the strand will get some input, produce output, get some new input, produce new output, and so forth, until they eventually produce a %done
with the actual final result.
Strands
Strands are the building blocks of threads. A thread will typically compose multiple strands.
A strand is a function of strand-input:strand -> output:strand
and is defined in /lib/strand/hoon
. You can see the details of strand-input
here and output:strand
here. At this stage you don't need to know the nitty-gritty but it's helpful to have a quick look through. We'll discuss these things in more detail later.
A strand is a core that has three important arms:
form
- the mold of the strandpure
- produces a strand that does nothing except return a valuebind
- monadic bind, likethen
in javascript promises
We'll discuss each of these arms later.
A strand must be specialised to produce a particular type like (strand ,<type>)
. As previously mentioned, a thread
produces a vase
so is specialised like (strand ,vase)
. Within your thread you'll likely compose multiple strands which produce different types like (strand ,@ud)
, (strand ,[path cage])
, etc, but the thread itself will always come back to a (strand ,vase)
.
Strands are conventionally given the face m
like:
=/ m (strand ,vase)...
NOTE: a comma prefix as in ,vase
is the irregular form of ^:
ketcol which produces a gate that returns the sample value if it's of the correct type, but crashes otherwise.
Form and Pure
form
The form
arm is the mold of the strand, suitable for casting. The two other arms produce form
s so you'll cast everything to this like:
=/ m (strand ,@ud)^- form:m...
pure
Pure produces a strand that does nothing except return a value. So, (pure:(strand ,@tas) %foo)
is a strand that produces %foo
without doing any IO.
We'll cover bind
later.
A trivial thread
/- spider=, strand=strand:spider^- thread:spider|= arg=vase=/ m (strand ,vase)^- form:m(pure:m arg)
The above code is a simple thread that just returns its argument, and it's a good boilerplate to start from.
Save the above code as a file in ted/mythread.hoon
and |commit
it. Run it with -mythread 'foo'
, you should see the following:
> -mythread 'foo'[~ 'foo']
NOTE: The dojo wraps arguments in a unit so that's why it's [~ 'foo']
rather than just 'foo'
.
Analysis
We'll go through it line-by line.
/- spider=, strand=strand:spider
First we import /sur/spider/hoon
which includes /lib/strand/hoon
and give the latter the face strand
for convenience.
^- thread:spider
We make it a thread by casting it to thread:spider
|= arg=vase
We create a gate that takes a vase, the first part of the previously mentioned thread definition.
=/ m (strand ,vase)
Inside the gate we create our strand
specialised to produce a vase
and give it the canonical face m
.
^- form:m
We cast the output to form
- the mold of the strand we created.
(pure:m arg)
Finally we call pure
with the gate input arg
as its argument. Since arg
is a vase
it will return the form
of a strand
which produces a vase
. Thus we've created a thread in accordance with its type definition.
Next we'll look at the third arm of a strand: bind
.