Angelo
tl;dr
- websocket support via
websocket('/path'){|s| ... }
route builder - SSE support via
eventsource('/path'){|s| ... }
route builder - contextual websocket/sse stashing via
websockets
andsses
helpers task
handling viaasync
andfuture
helpers- no rack
- erb, haml, and markdown support
- mustermann support
What is Angelo?
Just like Sinatra, Angelo gives you an expressive DSL for creating web applications. There are some
notable differences, but the basics remain the same: you can either create a "classic" application
by requiring 'angelo/main' and using the DSL at the top level of your script, or a "modular"
application by requiring 'angelo', subclassing Angelo::Base
, and calling .run!
on that class for the
service to start.
In addition, and perhaps more importantly, Angelo is built on Reel, which is built on
Celluloid::IO and gives you a reactor with evented IO in Ruby!
Things will feel very familiar to anyone experienced with Sinatra. You can define route handlers denoted by HTTP verb and path with parameters set from path matching (using Mustermann), the query string, and post body. A route block may return:
- The body of the response in full as a
String
. - A
Hash
(or anything thatrespond_to? :to_json
) if the content type is set to:json
. - Any object that responds to
#each(&block)
if the transfer encoding is set to:chunked
. There is also achunked_response
helper that will take a block, set the transfer encoding, and return an appropriate object.
Angelo also features before
and after
filter blocks, just like Sinatra. Filters are ordered as defined,
and called in that order. When defined without a path, they run for all matched requests. With a path,
the path is interpreted as a Mustermann pattern and params are merged. before
filters can set instance
variables which can be used in the route block and the after
filter.
For more info on the difference in how after blocks are handled, see the Errors section below for more info.
Websockets!
One of the main motivations for Angelo was the ability to define websocket handlers with ease. Through
the addition of a websocket
route builder and a websockets
helper, Angelo attempts to make it easy
for you to build real-time web applications.
Route Builder
The websocket
route builder accepts a path and a block, and passes the actual websocket to the block
as the only argument. This socket is an instance of Reel's
WebSocket class, and, as such,
responds to methods like on_message
and on_close
. A service-wide on_pong
handler may be defined
to customize the behavior when a pong frame comes back from a connected websocket client.
websockets
helper
Angelo includes a "stash" helper for connected websockets. One can <<
a websocket into websockets
from inside a websocket handler block. These can "later" be iterated over so one can do things like
emit a message on every connected websocket when the service receives a POST request.
The websockets
helper also includes a context ability, so you can stash connected websocket clients
into different "sections". Also, by default, the helper will reject!
any closed sockets before
returning; you may optionally pass false
to the helper to skip this step.
Example!
Here is an example of the websocket
route builder, the websockets
helper, and the context feature:
require 'angelo'
class Foo < Angelo::Base
websocket '/' do |ws|
websockets << ws
end
websocket '/bar' do |ws|
websockets[:bar] << ws
end
post '/' do
websockets.each {|ws| ws.write params[:foo]}
end
post '/bar' do
websockets[:bar].each {|ws| ws.write params[:bar]}
end
end
Foo.run!
In this case, any clients that connect to a websocket at the path '/' will be stashed in the
default websockets array; clients that connect to '/bar' will be stashed in the :bar
section.
Each "section" is accessed with a familiar, Hash
-like syntax, and can be iterated over with
a .each
block.
When a POST /
with a 'foo' param is received, any value is messaged out to all '/' connected
websockets. When a POST /bar
with a 'bar' param is received, any value is messaged out to all
websockets connected to '/bar'.
SSE - Server-Sent Events
The eventsource
route builder also accepts a path and a block, and passes the socket to the block,
just like the websocket
builder. This socket is actually the raw Celluloid::IO::TCPSocket
and is
"detached" from the regular handling. There are no "on-*" methods; the write
method should suffice.
To make it easier to deal with creation of the properly formatted Strings to send, Angelo provides
a couple helpers.
sse_event
helper
To create an "event" that a javascript EventListener on the client can respond to:
eventsource '/sse' do |s|
event = sse_event :foo, some_key: 'blah', other_key: 'boo'
s.write event
s.close
end
In this case, the EventListener would have to be configured to listen for the foo
event:
var sse = new EventSource('/sse');
sse.addEventListener('foo', function(e){ console.log("got foo event!\n" + JSON.parse(e.data)); });
The sse_event
helper accepts a normal String
for the data, but will automatically convert a Hash
argument to a JSON object.
NOTE: there is a shortcut helper on the actual SSE object itself:
eventsource '/sse' do |sse|
sse.event :foo, some_key: 'blah', other_key: 'boo'
sse.event :close
end
sse_message
helper
The sse_message
helper behaves exactly the same as sse_event
, but does not take an event name:
eventsource '/sse' do |s|
msg = sse_message some_key: 'blah', other_key: 'boo'
s.write msg
s.close
end
The client javascript would need to be altered to use the EventSource.onmessage
property as well:
var sse = new EventSource('/sse');
sse.onmessage = function(e){ console.log("got message!\n" + JSON.parse(e.data)); };
NOTE: there is a shortcut helper on the actual SSE object itself:
eventsource '/sse' do |sse|
sse.message some_key: 'blah', other_key: 'boo'
sse.event :close
end
sses
helper
Angelo also includes a "stash" helper for SSE connections. One can <<
a socket into sses
from
inside an eventsource
handler block. These can "later" be iterated over so one can do things
like emit a message on every SSE connection when the service receives a POST request.
The sses
helper includes the same context ability as the websockets
helper. Also, by default,
the helper will reject!
any closed sockets before returning, just like websockets
. You may
optionally pass false
to the helper to skip this step. In addition, the sses
stash includes
methods for easily sending events or messages to all stashed connections. Note that the
Stash::SSE#event
method only works on non-default contexts and uses the context name as the event
name.
eventsource '/sse' do |s|
sses[:foo] << s
end
post '/sse_message' do
sses[:foo].message params[:data]
end
post '/sse_event' do
sses[:foo].event params[:data]
end
eventsource
instance helper
Additionally, you can also start SSE handling conditionally from inside a GET block:
get '/sse_maybe' do
if params[:sse]
eventsource do |c|
sses << c
c.write sse_message 'wooo fancy SSE for you!'
end
else
'boring regular old get response'
end
end
post '/sse_event' do
sses.each {|sse| sse.write sse_event(:foo, 'fancy sse event!')}
end
Handling this on the client may require conditionals for browsers that do not support EventSource yet, since this will respond with a non-"text/event-stream" Content-Type if 'sse' is not present in the params.
EventSource#on_close
helper
When inside an eventsource block, you may want to do something specific when a client closes the
connection. For this case, there are on_close
and on_close=
methods on the object passed to the block
that will get called if the client closes the socket. The assignment method takes a proc object and the
other one takes a block:
get '/' do
eventsource do |es|
# assignment!
es.on_close = ->{sses(false).remove_socket es}
sses << es
end
end
eventsource '/sse' do |es|
# just passing a block here
es.on_close {sses(false).remove_socket es}
sses << es
end
Note the use of the optional parameter of the stashes here; by default, stash accessors (websockets
and
sses
) will reject!
any closed sockets before letting you in. If you pass false
to the stash
accessors, they will skip the reject!
step.
Tasks + Async / Future
Angelo is built on Reel and Celluloid::IO, giving your web application the ability to define
"tasks" and call them from route handler blocks in an async
or future
style.
task
builder
You can define a task on the reactor using the task
class method and giving it a symbol and a
block. The block can take arguments that you can pass later, with async
or future
.
# defining a task on the reactor called `:in_sec` which will sleep for
# the given number of seconds, then return the given message.
#
task :in_sec do |sec, msg|
sleep sec.to_i
msg
end
async
helper
This helper is directly analogous to the Celluoid method of the same name. Once tasks are defined, you can call them with this helper method, passing the symbol of the task name and any arguments. The task will run on the reactor, asynchronously, and return immediately.
get '/' do
# run the task defined above asynchronously, return immediately
#
async :in_sec, params[:sec], params[:msg]
# NOTE: params[:msg] is discarded, the return value of tasks called with `async` is nil.
# return this response body while the task is still running
# assuming params[:sec] is > 0
#
'hi'
end
future
helper
Just like async
, this comes from Celluloid as well. It behaves exactly like async
, with the
notable exception of returning a "future" object that you can call #value
on later to retrieve
the return value of the task. Calling #value
will "block" until the task is finished, while the
reactor continues to process requests.
get '/' do
# run the task defined above asynchronously, return immediately
#
f = future :in_sec, params[:sec], params[:msg]
# now, block until the task is finished and return the task's value
# as a response body
#
f.value
end
Errors and Halting
Angelo gives you two ordained methods of stopping route processing:
- raise an instance of
RequestError
halt
with a status code and message
The main difference is that halt
will still run after
blocks, and raising RequestError
will bypass after
blocks.
Any other exceptions or errors raised by your route handler will be handled with a 500 status code and the message will be the body of the response.
RequestError
Raising an instance of Angelo::RequestError
causes a 400 status code response, and the message
in the instance is the body of the the response. If the route or class was set to respond with
JSON, the body is converted to a JSON object with one key, error
, that has the value of the message.
If the message is a Hash
, the hash is converted to a JSON object, or to a string for other content
types.
If you want to return a different status code, you can pass it as a second argument to
RequestError.new
. See example below.
Halting
You can halt
from within any route handler, optionally passing status code and a body. The
body is handled the same way as raising RequestError
.
Example
get '/' do
raise RequestError.new '"foo" is a required parameter' unless params[:foo]
params[:foo]
end
get '/json' do
content_type :json
raise RequestError.new foo: "required!"
{foo: params[:foo]}
end
get '/not_found' do
raise RequestError.new 'not found', 404
end
get '/halt' do
halt 200, "everything's fine"
raise RequestError.new "won't get here"
end
$ curl -i http://127.0.0.1:4567/
HTTP/1.1 400 Bad Request
Content-Type: text/html
Connection: Keep-Alive
Content-Length: 29
"foo" is a required parameter
$ curl -i http://127.0.0.1:4567/?foo=bar
HTTP/1.1 200 OK
Content-Type: text/html
Connection: Keep-Alive
Content-Length: 3
bar
$ curl -i http://127.0.0.1:4567/json
HTTP/1.1 400 Bad Request
Content-Type: application/json
Connection: Keep-Alive
Content-Length: 29
{"error":{"foo":"required!"}}
$ curl -i http://127.0.0.1:4567/not_found
HTTP/1.1 404 Not Found
Content-Type: text/html
Connection: Keep-Alive
Content-Length: 9
not found
$ curl -i http://127.0.0.1:4567/halt
HTTP/1.1 200 OK
Content-Type: text/html
Connection: Keep-Alive
Content-Length: 18
everything's fine
Tilt / ERB
class Foo < Angelo::Base
views_dir 'some/other/path' # defaults to './views'
get '/' do
erb :index
end
end
The Angleo::Tilt::ERB module and the erb
method do some extra work for you:
- templates are pre-compiled, sorted by type.
- template type is determined by word between name and .erb (ex:
index.html.erb
is:index
name and:html
type) - the template chosen to render is determined based on:
:type
option passed toerb
helperAccept
request header valueContent-Type
response header value- default to
:html
See views for examples.
Mustermann
class Foo < Angelo::Base
get '/:foo/things/:bar' do
# `params` is merged with the Mustermann object#params hash, so
# a "GET /some/things/are_good?foo=other&bar=are_bad" would have:
# params: {
# 'foo' => 'some',
# 'bar' => 'are_good'
# }
@foo = params[:foo]
@bar = params[:bar]
erb :index
end
before '/:fu/things/*' do
# `params` is merged with the Mustermann object#params hash, as
# parsed with the current request path against this before block's
# pattern. in the route handler, `params[:fu]` is no longer available.
@fu = params[:fu]
end
end
Classic vs. modular apps
Like Sinatra, Angelo apps can be written in either "classic" style or so-called "modular" style. Which style you use is more of a personal preference than anything else.
A classic-style app requires "angelo/main" and defines the app directly at the top level using the DSL. In addition, classic apps:
- Can use a
helpers
block to define methods that can be called from filters and route handlers. Thehelpers
method can also include methods from one or more modules passed as arguments instead of or in addition to taking a block. - Parse optional command-line options "-o addr" and "-p port" to set the bind address and listen port, respectively.
- Are run automatically.
Note: unlike Sinatra, define a classic app by requiring "angelo/main" and a modular app by requiring "angelo". Sinatra uses "sinatra" and "sinatra/base" to do the same things.
Here's a classic app:
require 'angelo/main'
helpers do
def say_hello
"Hello"
end
end
get "/hello" do
"#{say_hello} to you, too."
end
And the same app in modular style:
require 'angelo'
class HelloApp < Angelo::Base
def say_hello
"Hello"
end
get "/hello" do
"#{say_hello} to you, too."
end
end
HelloApp.run!
JSON HTTP API
If you post JSON data with a JSON Content-Type, angelo will:
- merge objects into the
params
SymHash - parse arrays and make them available via
request_body
N.B. request_body
is functionally equivalent to request.body.to_s
otherwise.
If your content_type
is set to :json
, angelo will convert:
- anything returned from a route block that
respond_to? :to_json
RequestError
message datahalt
data
Documentation
I'm bad at documentation and I feel bad.
Others have helped, and there is a YaRD plugin for Angelo here if you would like to document your apps built with Angelo. (thanks: @katjaeinsfeld, @artcom)
WORK LEFT TO DO
Lots of work left to do!
Full-ish example
require 'angelo'
class Foo < Angelo::Base
# just some constants to use in routes later...
#
TEST = {foo: "bar", baz: 123, bat: false}.to_json
HEART = '<3'
# a flag to know if the :heart task is running
#
@@hearting = false
# you can define instance methods, just like Sinatra!
#
def pong; 'pong'; end
def foo; params[:foo]; end
# standard HTTP GET handler
#
get '/ping' do
pong
end
# standard HTTP POST handler
#
post '/foo' do
foo
end
post '/bar' do
params.to_json
end
# emit the TEST JSON value on all :emit_test websockets
# return the params posted as JSON
#
post '/emit' do
websockets[:emit_test].each {|ws| ws.write TEST}
params.to_json
end
# handle websocket requests at '/ws'
# stash them in the :emit_test context
# write 6 messages to the websocket whenever a message is received
#
websocket '/ws' do |ws|
websockets[:emit_test] << ws
ws.on_message do |msg|
5.times { ws.write TEST }
ws.write foo.to_json
end
end
# emit the TEST JSON value on all :other websockets
#
post '/other' do
websockets[:other].each {|ws| ws.write TEST}
''
end
# stash '/other/ws' connected websockets in the :other context
#
websocket '/other/ws' do |ws|
websockets[:other] << ws
end
websocket '/hearts' do |ws|
# this is a call to Base#async, actually calling
# the reactor to start the task
#
async :hearts unless @@hearting
websockets[:hearts] << ws
end
# this is a call to Base.task, defining the task
# to perform on the reactor
#
task :hearts do
@@hearting = true
every(10){ websockets[:hearts].each {|ws| ws.write HEART } }
end
post '/in/:sec/sec/:msg' do
# this is a call to Base#future, telling the reactor
# do this thing and we'll want the value eventually
#
f = future :in_sec, params[:sec], params[:msg]
f.value
end
# define a task on the reactor that sleeps for the given number of
# seconds and returns the given message
#
task :in_sec do |sec, msg|
sleep sec.to_i
msg
end
# return a chunked response of JSON for 5 seconds
#
get '/chunky_json' do
content_type :json
# this helper requires a block that takes one arg, the response
# proc to call with each chunk (i.e. the block that is passed to
# `#each`)
#
chunked_response do |response|
5.times do
response.call time: Time.now.to_i
sleep 1
end
end
end
end
Foo.run!
Contributing
Anyone is welcome to contribute. Conduct is guided by the Contributor Covenant.
See code_of_conduct.md
.
To contribute to Angelo, please:
- fork the repository to your GitHub account
- create a branch for the feature or fix
- commit your changes to that branch, please include tests if applicable
- submit a Pull Request back to the main repository's
master
branch
After review and acceptance, your changes will be merged and noted in CHANGLOG.md
.
Testing
Unit tests are done with Minitest. Run them with :
bundle install
rake test
License
Name
Why the name "Angelo"? Since the project mimics Sinatra's DSL, I thought it best to keep a reference to The Chairman in the name. It turns out that Frank Sinatra won an Academy Award for his role 'Angelo Maggio' in 'From Here to Eternity'. I appropriated the name since this is like Sinatra on Reel (film).