8a34e4c28f | ||
---|---|---|
.. | ||
impl | ||
values | ||
vocab | ||
README.md | ||
gen_consts.go | ||
gen_doc.go | ||
gen_init.go | ||
gen_json_resolver.go | ||
gen_manager.go | ||
gen_pkg_activitystreams_disjoint.go | ||
gen_pkg_activitystreams_extendedby.go | ||
gen_pkg_activitystreams_extends.go | ||
gen_pkg_activitystreams_isorextends.go | ||
gen_pkg_activitystreams_property_constructors.go | ||
gen_pkg_activitystreams_type_constructors.go | ||
gen_pkg_gotosocial_disjoint.go | ||
gen_pkg_gotosocial_extendedby.go | ||
gen_pkg_gotosocial_extends.go | ||
gen_pkg_gotosocial_isorextends.go | ||
gen_pkg_gotosocial_property_constructors.go | ||
gen_pkg_gotosocial_type_constructors.go | ||
gen_pkg_jsonld_property_constructors.go | ||
gen_pkg_schema_disjoint.go | ||
gen_pkg_schema_extendedby.go | ||
gen_pkg_schema_extends.go | ||
gen_pkg_schema_isorextends.go | ||
gen_pkg_schema_property_constructors.go | ||
gen_pkg_schema_type_constructors.go | ||
gen_pkg_toot_disjoint.go | ||
gen_pkg_toot_extendedby.go | ||
gen_pkg_toot_extends.go | ||
gen_pkg_toot_isorextends.go | ||
gen_pkg_toot_property_constructors.go | ||
gen_pkg_toot_type_constructors.go | ||
gen_pkg_w3idsecurityv1_disjoint.go | ||
gen_pkg_w3idsecurityv1_extendedby.go | ||
gen_pkg_w3idsecurityv1_extends.go | ||
gen_pkg_w3idsecurityv1_isorextends.go | ||
gen_pkg_w3idsecurityv1_property_constructors.go | ||
gen_pkg_w3idsecurityv1_type_constructors.go | ||
gen_resolver_utils.go | ||
gen_type_predicated_resolver.go | ||
gen_type_resolver.go | ||
util.go |
README.md
streams
ActivityStreams vocabularies automatically code-generated with astool
.
Reference & Tutorial
The go-fed website contains tutorials and reference materials, in addition to the rest of this README.
How To Use
go get github.com/go-fed/activity
All generated types and properties are interfaces in
github.com/go-fed/streams/vocab
, but note that the constructors and supporting
functions live in github.com/go-fed/streams
.
To create a type and set properties:
var actorURL *url.URL = // ...
// A new "Create" Activity.
create := streams.NewActivityStreamsCreate()
// A new "actor" property.
actor := streams.NewActivityStreamsActorProperty()
actor.AppendIRI(actorURL)
// Set the "actor" property on the "Create" Activity.
create.SetActivityStreamsActor(actor)
To process properties on a type:
// Returns true if the "Update" has at least one "object" with an IRI value.
func hasObjectWithIRIValue(update vocab.ActivityStreamsUpdate) bool {
objectProperty := update.GetActivityStreamsObject()
// Any property may be nil if it was either empty in the original JSON or
// never set on the golang type.
if objectProperty == nil {
return false
}
// The "object" property is non-functional: it could have multiple values. The
// generated code has slightly different methods for a functional property
// versus a non-functional one.
//
// While it may be easy to ignore multiple values in other languages
// (accidentally or purposefully), go-fed is designed to make it hard to do
// so.
for iter := objectProperty.Begin(); iter != objectProperty.End(); iter = iter.Next() {
// If this particular value is an IRI, return true.
if iter.IsIRI() {
return true
}
}
// All values are literal embedded values and not IRIs.
return false
}
The ActivityStreams type hierarchy of "extends" and "disjoint" is not the same as the Object Oriented definition of inheritance. It is also not the same as golang's interface duck-typing. Helper functions are provided to guarantee that an application's logic can correctly apply the type hierarchy.
thing := // Pick a type from streams.NewActivityStreams<Type>()
if streams.ActivityStreamsObjectIsDisjointWith(thing) {
fmt.Printf("The \"Object\" type is Disjoint with the %T type.\n", thing)
}
if streams.ActivityStreamsLinkIsExtendedBy(thing) {
fmt.Printf("The %T type Extends from the \"Link\" type.\n", thing)
}
if streams.ActivityStreamsActivityExtends(thing) {
fmt.Printf("The \"Activity\" type extends from the %T type.\n", thing)
}
When given a generic JSON payload, it can be resolved to a concrete type by
creating a streams.JSONResolver
and giving it a callback function that accepts
the interesting concrete type:
// Callbacks must be in the form:
// func(context.Context, <TypeInterface>) error
createCallback := func(c context.Context, create vocab.ActivityStreamsCreate) error {
// Do something with 'create'
fmt.Printf("createCallback called: %T\n", create)
return nil
}
updateCallback := func(c context.Context, update vocab.ActivityStreamsUpdate) error {
// Do something with 'update'
fmt.Printf("updateCallback called: %T\n", update)
return nil
}
jsonResolver, err := streams.NewJSONResolver(createCallback, updateCallback)
if err != nil {
// Something in the setup was wrong. For example, a callback has an
// unsupported signature and would never be called
panic(err)
}
// Create a context, which allows you to pass data opaquely through the
// JSONResolver.
c := context.Background()
// Example 15 of the ActivityStreams specification.
b := []byte(`{
"@context": "https://www.w3.org/ns/activitystreams",
"summary": "Sally created a note",
"type": "Create",
"actor": {
"type": "Person",
"name": "Sally"
},
"object": {
"type": "Note",
"name": "A Simple Note",
"content": "This is a simple note"
}
}`)
var jsonMap map[string]interface{}
if err = json.Unmarshal(b, &jsonMap); err != nil {
panic(err)
}
// The createCallback function will be called.
err = jsonResolver.Resolve(c, jsonMap)
if err != nil && !streams.IsUnmatchedErr(err) {
// Something went wrong
panic(err)
} else if streams.IsUnmatchedErr(err) {
// Everything went right but the callback didn't match or the ActivityStreams
// type is one that wasn't code generated.
fmt.Println("No match: ", err)
}
A streams.TypeResolver
is similar but uses the golang types instead. It
accepts the generic vocab.Type
. This is the abstraction when needing to handle
any ActivityStreams type. The function ToType
can convert a JSON-decoded-map
into this kind of value if needed.
A streams.PredicatedTypeResolver
lets you apply a boolean predicate function
that acts as a check whether a callback is allowed to be invoked.
FAQ
Why Are Empty Properties Nil And Not Zero-Valued?
Due to implementation design decisions, it would require a lot of plumbing to ensure this would work properly. It would also require allocation of a non-trivial amount of memory.