If you are working on a Gall agent with any kind of web interface, it's likely you will encounter the problem of converting Hoon data structures to JSON and vice versa. This is what we'll examine in this document.
Urbit represents JSON data with the $json
structure (defined in lull.hoon
). You can refer to the json type section below for details.
JSON data on the web is encoded in text, so Urbit has two functions in zuse.hoon
for dealing with this:
+en:json:html
- For printing$json
to a text-encoded form.+de:json:html
- For parsing text-encoded JSON to a$json
structure.
You typically want $json
data converted to some other noun
structure or vice versa, so Urbit has three collections of functions for this purpose, also in zuse.hoon
:
+enjs:format
- Functions for converting various atoms and structures to$json
.+dejs:format
- Many "reparsers" for converting$json
data to atoms and other structures.+dejs-soft:format
- Largely the same as+dejs:format
except its reparsers produceunit
s which are null upon failure rather than simply crashing.
The relationship between these types and functions look like this:
Note this diagram is a simplification - the +dejs:format
and +enjs:format
collections in particular are tools to be used in writing conversion functions rather than simply being used by themselves, but it demonstrates the basic relationships. Additionally, it is less common to do printing/parsing manually - this would typically be handled automatically by Eyre, though it may be necessary if you're retrieving JSON data via the web client vane Iris.
In practice
A typical Gall agent will have a number of structures defined in a file in the /sur
directory. These will define the type of data it expects to be %poke
ed with, the type of data it will %give
to subscribers, and the type of data its scry endpoints produce.
If the agent only interacts with other agents inside Urbit, it may just use a %noun
mark
. If, however, it needs to talk to a web interface of some kind, it usually must handle $json
data with a %json
mark.
Sometimes an agent's interactions with a web interface are totally distinct from its interactions with other agents. If so, the agent could just have separate scry endpoints, poke handlers, etc, that directly deal with $json
data with a %json
mark. In such a case, you can include $json
encoding/decoding functions directly in the agent or associated libraries, using the general techniques demonstrated in the $json encoding and decoding example section below.
If, on the other hand, you want a unified interface (whether interacting with a web client or within Urbit), a different approach is necessary. Rather than taking or producing either %noun
or %json
marked data, custom mark
files can be created which specify conversion methods for both %noun
and %json
marked data.
With this approach, an agent would take and/or produce data with some mark
like %my-custom-mark
. Then, when the agent must interact with a web client, the webserver vane Eyre can automatically convert %my-custom-mark
to %json
or vice versa. This way the agent only ever has to handle the %my-custom-mark
data. This approach is used by %graph-store
with its %graph-update-2
mark, for example, and a number of other agents.
For details of creating a mark
file for this purpose, the mark file example section below walks through a practical example.
The $json
type
Urbit represents JSON data with the $json
structure (defined in /sys/lull.hoon
):
+$ json :: normal json value$@ ~ :: null$% [%a p=(list json)] :: array[%b p=?] :: boolean[%o p=(map @t json)] :: object[%n p=@ta] :: number[%s p=@t] :: string== ::
The correspondence of $json
to JSON types is fairly self-evident, but here's a table comparing the two for additional clarity:
JSON Type | $json Type | JSON Example | $json Example |
---|---|---|---|
Null | ~ | null | ~ |
Boolean | [%b p=?] | true | [%b p=%.y] |
Number | [%n p=@ta] | 123 | [%n p=~.123] |
String | [%s p=@t] | "foo" | [%s p='foo'] |
Array | [%a p=(list json)] | ["foo",123] | [%a p=~[[%s p='foo'] [%n p=~.123]]] |
Object | [%o p=(map @t json)] | {"foo":"xyz","bar":123} | [%o p={[p='bar' q=[%n p=~.123]] [p='foo' q=[%s p='xyz']]}] |
Since the $json
%o
object and %a
array types may themselves contain any $json
, you can see how JSON structures of arbitrary complexity can be represented. Note the %n
number type is a @ta
rather than something like a @ud
that you might expect. This is because JSON's number type may be either an integer or floating point, so it's left as a knot
which can then be parsed to a @ud
or @rd
with the appropriate +dejs:format
function.
$json
encoding and decoding example
Let's have a look at a practical example. Here's a core with three arms. It has the structure arm $user
, and then two more: +to-js
converts a $user
structure to $json
, and +from-js
does the opposite. Usually we'd define the structure in a separate /sur
file, but for simplicity it's all in the one core.
json-test.hoon
|%+$ user$: username=@tname=[first=@t mid=@t last=@t]joined=@daemail=@t==++ to-js|= usr=user|^ ^- json%- pairs:enjs:format:~['username' s+username.usr]['name' name]['joined' (sect:enjs:format joined.usr)]['email' s+email.usr]==++ name:- %a:~[%s first.name.usr][%s mid.name.usr][%s last.name.usr]==--++ from-js=, dejs:format^- $-(json user)%- ot:~[%username so][%name (at ~[so so so])][%joined du][%email so]==--
Note: This example (and a couple of others in this guide) sometimes use a syntax of foo+bar
. This is just syntactic sugar to tag the head of bar
with the term
constant %foo
, and is equivalent to [%foo bar]
. Since json
data is a union with head tags of %b
, %n
, %s
, %a
, or %o
, it's sometimes convenient to do s+'some string'
, b+&
, etc.
Try it out
First we'll try using our $json
encoding/decoding library, and afterwards we'll take a closer look at its construction. To begin, save the code above in /lib/json-test.hoon
of the %base
desk on a fake ship and |commit
it:
> |commit %base>=+ /~zod/base/5/lib/json-test/hoon
Then we need to build it so we can use it. We'll give it a face of user-lib
:
> =user-lib -build-file %/lib/json-test/hoon
Let's now create an example of a $user
structure:
> =usr `user:user-lib`['john456' ['John' 'William' 'Smith'] now 'john.smith@example.com']> usr[ username='john456'name=[first='John' mid='William' last='Smith']joined=~2021.9.12..09.47.58..1b65email='john.smith@example.com']
Now we can try calling the +to-js
function with our data to convert it to $json
:
> =usr-json (to-js:user-lib usr)> usr-json[ %op{ [p='email' q=[%s p='john.smith@example.com']][p='name' q=[%a p=~[[%s p='John'] [%s p='William'] [%s p='Smith']]]][p='username' q=[%s p='john456']][p='joined' q=[%n p=~.1631440078]]}]
Let's also see how that $json
would look as real JSON encoded in text. We can do that with +en:json:html
:
> (en:json:html (to-js:user-lib usr))'{"joined":1631440078,"username":"john456","name":["John","William","Smith"],"email":"john.smith@example.com"}'
Finally, let's try converting the $json
back to a $user
again with our +from-js
arm:
> (from-js:user-lib usr-json)[ username='john456'name=[first='John' mid='William' last='Smith']joined=~2021.9.12..09.47.58email='john.smith@example.com']
Analysis
Converting to $json
Here's our arm that converts a $user
structure to $json
:
++ to-js|= usr=user|^ ^- json%- pairs:enjs:format:~['username' s+username.usr]['name' name]['joined' (sect:enjs:format joined.usr)]['email' s+email.usr]==++ name:- %a:~[%s first.name.usr][%s mid.name.usr][%s last.name.usr]==--
There are different ways we could represent our $user
structure as JSON, but in this case we've opted to encapsulate it in an object and have the name
as an array (since JSON arrays preserve order).
+enjs:format
includes the convenient +pairs
function, which converts a list of [@t json]
to an object containing those key-value pairs. We've used this to assemble the final object. Note that if you happen to have only a single key-value pair rather than a list, you can use +frond
instead of +pairs
.
For the joined
field, we've used the +sect
function from +enjs
to convert the @da
to a Unix seconds timestamp in a $json
number. The +sect
function, like others in +enjs
, takes in a noun (in this case a @da
) and produces $json
(in this case a [%n @ta]
number). +enjs
contains a handful of useful functions like this, but for the rest we've just hand-made the $json
structure. This is fairly typical when encoding $json
, it's usually decoding that makes more extensive use of the $json
utility functions in +format
.
For the name
field we've just formed a cell of %a
and a list of $json
strings, since a $json
array is [%a p=(list json)]
. Note we've separated this part into its own arm and wrapped the whole thing in a |^
- a core with a $
arm that's computed immediately. This is simply for readability - our structure here is quite simple but when dealing with deeply-nested $json
structures or complex logic, having a single giant function can quickly become unwieldy.
Converting from $json
Here's our arm that converts $json
to our $user
structure:
++ from-js=, dejs:format^- $-(json user)%- ot:~[%username so][%name (at ~[so so so])][%joined du][%email so]==
This is the inverse of the encoding function described in the previous section.
We make extensive use of +dejs:format
functions here, so we've used =,
to expose the namespace and allow succinct +dejs
function calls.
We use the +ot
function from +dejs:format
to decode the $json
object to a n-tuple. It's a wet gate that takes a list of pairs of keys and other +dejs
functions and produces a new gate that takes the $json
to be decoded (which we've given it in jon
).
The +so
functions just decode $json
strings to cord
s. The +at
function converts a $json
array to a tuple, decoding each element with the respective function given in its argument list. Like +ot
, +at
is also a wet gate that produces a gate that takes $json
. In our case we've used +so
for each element, since they're all strings.
For joined
, we've used the +du
function, which converts a Unix seconds timestamp in a $json
number to a @da
(it's basically the inverse of the +sect:enjs:format
we used earlier).
Notice how +ot
takes in other +dejs
functions in its argument. One of its arguments includes the +at
function which itself takes in other +dejs
functions. There are several +dejs
functions like this that allow complex nested JSON structures to be decoded. For other examples of common +dejs
functions like this, see the More +dejs
section below.
There are dozens of different functions in +dejs:format
that will cover a great many use cases. If there isn't a +dejs
function for a particular case, you can also just write a custom function - it just has to take $json
. Note there's also the +dejs-soft:format
functions - these are similar to +dejs
functions except they produce unit
s rather than simply crashing if decoding fails.
More +dejs
We looked at the commonly used +ot
function in the first example, now let's look at a couple more common +dejs
functions.
+of
The +of
function takes an object containing a single key-value pair, decodes the value with the corresponding +dejs
function in a key-function list, and produces a key-value tuple. This is useful when there are multiple possible objects you might receive, and tagged unions are a common data structure in hoon.
Let's look at an example. Here's a gate that takes in some $json
, decodes it with an +of
function that can handle three possible objects, casts the result to a tagged union, switches against its head with ?-
, performs some transformation and finally returns the result. You can save it as gen/of-test.hoon
in the %base
desk of a fake ship and |commit %base
.
of-test.hoon
|= jon=json|^ ^- @t=/ =fbb(to-fbb jon)?- -.fbb%foo (cat 3 +.fbb '!!!')%bar ?:(+.fbb 'Yes' 'No')%baz :((cury cat 3) p.fbb q.fbb r.fbb)==+$ fbb$% [%foo @t][%bar ?][%baz p=@t q=@t r=@t]==++ to-fbb=, dejs:format%- of:~ foo+sobar+bobaz+(at ~[so so so])==--
Let's try it:
> +of-test (need (de:json:html '{"foo":"Hello"}'))'Hello!!!'> +of-test (need (de:json:html '{"bar":true}'))'Yes'> +of-test (need (de:json:html '{"baz":["a","b","c"]}'))'abc'
+ou
The +ou
function decodes a $json
object to an n-tuple using the matching functions in a key-function list. Additionally, it lets you set some key-value pairs in an object as optional and others as mandatory. The mandatory ones crash if they're missing and the optional ones are replaced with a given noun.
+ou
is different to other +dejs
functions - the functions it takes are $-((unit json) grub)
rather than the usual $-(json grub)
of most +dejs
functions. There are only two +dejs
functions that fit this - +un
and +uf
. These are intended to be used with +ou
- you would wrap each function in the key-function list of +ou
with either +un
or +uf
.
+un
crashes if its argument is ~
. +ou
gives functions a ~
if the matching key-value pair is missing in the $json
object, so +un
crashes if the key-value pair is missing. Therefore, +un
lets you set key-value pairs as mandatory.
+uf
takes two arguments - a noun and a +dejs
function. If the (unit json)
it's given by +ou
is ~
, it produces the noun it was given rather than the product of the +dejs
function. This lets you specify key-value pairs as optional, replacing missing ones with whatever you want.
Let's look at a practical example. Here's a generator you can save in the %base
desk of a fake ship in gen/ou-test.hoon
and |commit %base
. It takes in a $json
object and produces a triple. The +ou
in +decode
has three key-function pairs - the first two are mandatory and the last is optional, producing the bunt of a set if the %baz
key is missing.
ou-test.hoon
|= jon=json|^ ^- [@t ? (set @ud)](decode jon)++ decode=, dejs:format%- ou:~ foo+(un so)bar+(un bo)baz+(uf *(set @ud) (as ni))==--
Let's try it:
> +ou-test (need (de:json:html '{"foo":"hello","bar":true,"baz":[1,2,3,4]}'))['hello' %.y {1 2 3 4}]> +ou-test (need (de:json:html '{"foo":"hello","bar":true}'))['hello' %.y {}]> +ou-test (need (de:json:html '{"foo":"hello"}'))[%key 'bar']dojo: hoon expression failed
+su
The +su
function parses a string with the given parsing rule
. Hoon's functional parsing library is very powerful and lets you create arbitrarily complex parsers. JSON will often have data types encoded in strings, so this function can be very useful. The writing of parsers is outside the scope of this guide, but you can see the Parsing Guide and sections 4e to 4j of the standard library documentation for details.
Here are some simple examples of using +su
to parse strings:
> `@ux`((su:dejs:format hex) s+'deadbeef1337f00D')0xdead.beef.1337.f00d> `(list @)`((su:dejs:format (most lus dem)) s+'1+2+3+4')~[1 2 3 4]> `@ub`((su:dejs:format ven) s+'+>-<->+<+')0b11.1000.1101
Here's a more complex parser that will parse a GUID like 824e7749-4eac-9c00-db16-4cb816cd6f19
to a @ux
:
su-test.hoon
|= jon=json^- @ux%. jon%- su:dejs:format%+ cook|= parts=(list [step @])^- @ux(can 3 (flop parts));~ plug(stag 4 ;~(sfix (bass 16 (stun 8^8 six:ab)) hep))(stag 2 ;~(sfix qix:ab hep))(stag 2 ;~(sfix qix:ab hep))(stag 2 ;~(sfix qix:ab hep))(stag 6 (bass 16 (stun 12^12 six:ab)))(easy ~)==
Save it in the /gen
directory of the %base
desk and |commit
it. We can then try it with:
> +su-test s+'5323a61d-0c26-d8fa-2b73-18cdca805fd8'0x5323.a61d.0c26.d8fa.2b73.18cd.ca80.5fd8
If we delete the last character it'll no longer be a valid GUID and the parsing will fail:
> +su-test s+'5323a61d-0c26-d8fa-2b73-18cdca805fd'/gen/su-test/hoon:<[2 1].[16 3]>/gen/su-test/hoon:<[3 1].[16 3]>{1 36}syntax errordojo: naked generator failure
mark
file example
Here's a simple mark
file for the $user
structure we created in the first example. It imports the json-test.hoon library we created and saved in our %base
desk's /lib
directory.
user.hoon
/+ *json-test|_ usr=user++ grab|%++ noun user++ json from-js--++ grow|%++ noun usr++ json (to-js usr)--++ grad %noun--
The Marks section of the Clay documentation covers mark
files comprehensively and is worth reading through if you want to write a mark file.
In brief, a mark file contains a door
with three arms. The door's sample type is the type of the data in question - in our case the $user
structure. The +grab
arm contains methods for converting to our mark, and the +grow
arm contains methods for converting from our mark. The +noun
arms are mandatory, and then we've added +json
arms which respectively call the +from-js
and +to-js
functions from our json-test.hoon
library. The final +grad
arm defines various revision control functions, in our case we've delegated these to the %noun
mark.
From this mark file, Clay can build mark conversion gates between the %json
mark and our %user
mark, allowing the conversion of $json
data to a $user
structure and vice versa.
Try it out
First, we'll save the code above as user.hoon
in the /mar
directory our of %base
desk:
> |commit %base>=+ /~zod/base/9/mar/user/hoon
Let's quickly create a $json
object to work with:
> =jon (need (de:json:html '{"joined":1631440078,"username":"john456","name":["John","William","Smith"],"email":"john.smith@example.com"}'))> jon[ %op{ [p='email' q=[%s p='john.smith@example.com']][p='name' q=[%a p=~[[%s p='John'] [%s p='William'] [%s p='Smith']]]][p='username' q=[%s p='john456']][p='joined' q=[%n p=~.1631440078]]}]
We'll also build our library so we can use its types from the dojo:
> =user-lib -build-file %/lib/json-test/hoon
Now we can ask Clay to build a mark conversion gate from a %json
mark to our %user
mark. We'll use a scry with a %f
care
which produces a static mark conversion gate:
> =json-to-user .^($-(json user:user-lib) %cf /===/json/user)
Let's try converting our $json
to a $user
structure with our new mark conversion gate:
> =usr (json-to-user jon)> usr[ username='john456'name=[first='John' mid='William' last='Smith']joined=~2021.9.12..09.47.58email='john.smith@example.com']
Now let's try the other direction. We'll again scry Clay to build a static mark conversion gate, this time from %user
to %json
rather than the reverse:
> =user-to-json .^($-(user:user-lib json) %cf /===/user/json)
Let's test it out by giving it our $user
data:
> (user-to-json usr)[ %op{ [p='email' q=[%s p='john.smith@example.com']][p='name' q=[%a p=~[[%s p='John'] [%s p='William'] [%s p='Smith']]]][p='username' q=[%s p='john456']][p='joined' q=[%n p=~.1631440078]]}]
Finally, let's see how that looks as JSON encoded in text:
> (en:json:html (user-to-json usr))'{"joined":1631440078,"username":"john456","name":["John","William","Smith"],"email":"john.smith@example.com"}'
Usually (though not in all cases) these mark conversions will be performed implicitly by Gall or Eyre and you'd not deal with the mark conversion gates directly, but it's still informative to see them work explicitly.
Further reading
The Zuse library reference - This includes documentation of the JSON parsing, printing, encoding and decoding functions.
The Marks section of the Clay documentation - Comprehensive documentation of mark
s.
The External API Reference section of the Eyre documentation - Details of the webserver vane Eyre's external API.
The Iris documentation - Details of the web client vane Iris, which may be used to fetch external JSON data among other things.
Strings Guide - Atom printing functions like +scot
will often be useful for JSON encoding - see the Encoding in Text section for usage.
Parsing Guide - Learn how to write functional parsers in hoon which can be used with +su
.