Skip to content

clojurecademy/aleph

 
 

Repository files navigation

Clojars Project cljdoc badge CircleCI

Aleph exposes data from the network as a Manifold stream, which can easily be transformed into a java.io.InputStream, core.async channel, Clojure sequence, or many other byte representations. It exposes simple default wrappers for HTTP, TCP, and UDP, but allows access to full performance and flexibility of the underlying Netty library.

Leiningen:

[aleph "0.6.0"]

deps.edn:

aleph/aleph {:mvn/version "0.6.0"}
;; alternatively
io.github.clj-commons/aleph {:git/sha "..."}

HTTP

Aleph follows the Ring spec fully, and can be a drop-in replacement for any existing Ring-compliant server. However, it also allows for the handler function to return a Manifold deferred to represent an eventual response. This feature may not play nicely with synchronous Ring middleware which modifies the response, but this can be easily fixed by reimplementing the middleware using Manifold's let-flow operator. The aleph.http/wrap-ring-async-handler helper can be used to convert async 3-arity Ring handler to Aleph-compliant one.

(require '[aleph.http :as http])

(defn handler [req]
  {:status 200
   :headers {"content-type" "text/plain"}
   :body "hello!"})

(http/start-server handler {:port 8080})

The body of the response may also be a Manifold stream, where each message from the stream is sent as a chunk, allowing for precise control over streamed responses for server-sent events and other purposes.

For HTTP client requests, Aleph models itself after clj-http, except that every request immediately returns a Manifold deferred representing the response.

(require
  '[manifold.deferred :as d]
  '[clj-commons.byte-streams :as bs])

(-> @(http/get "https://google.com/")
    :body
    bs/to-string
    prn)

(d/chain (http/get "https://google.com")
         :body
         bs/to-string
         prn)

Aleph attempts to mimic the clj-http API and capabilities fully. It supports multipart/form-data requests, cookie stores, proxy servers and requests inspection with a few notable differences:

  • proxy configuration should be set for the connection when seting up a connection pool, per-request proxy setups are not allowed

  • HTTP proxy functionality is extended with tunneling settings, optional HTTP headers and connection timeout control, see all configuration keys

  • :proxy-ignore-hosts is not supported

  • both cookies middleware and built-in cookies storages do not support cookie params obsoleted since RFC2965: comment, comment URL, discard, version (see the full structure of the cookie)

  • when using :debug, :save-request? and :debug-body? options, corresponding requests would be stored in :aleph/netty-request, :aleph/request, :aleph/request-body keys of the response map

  • :response-interceptor option is not supported

  • Aleph introduces :log-activity connection pool configuration to switch on the logging of the connections status changes as well as requests/response hex dumps

  • :cache and :cache-config options are not supported as for now

Aleph client also supports fully async and highly customizable DNS resolver.

To learn more, read the example code.

WebSockets

On any HTTP request which has the proper Upgrade headers, you may call (aleph.http/websocket-connection req), which returns a deferred which yields a duplex stream, which uses a single stream to represent bidirectional communication. Messages from the client can be received via take!, and sent to the client via put!. An echo WebSocket handler, then, would just consist of:

(require '[manifold.stream :as s])

(defn echo-handler [req]
  (let [s @(http/websocket-connection req)]
    (s/connect s s)))

This takes all messages from the client, and feeds them back into the duplex socket, returning them to the client. WebSocket text messages will be emitted as strings, and binary messages as byte arrays.

WebSocket clients can be created via (aleph.http/websocket-client url), which returns a deferred which yields a duplex stream that can send and receive messages from the server.

To learn more, read the example code.

TCP

A TCP server is similar to an HTTP server, except that for each connection the handler takes two arguments: a duplex stream and a map containing information about the client. The stream will emit byte-arrays, which can be coerced into other byte representations using the byte-streams library. The stream will accept any messages which can be coerced into a binary representation.

An echo TCP server is very similar to the above WebSocket example:

(require '[aleph.tcp :as tcp])

(defn echo-handler [s info]
  (s/connect s s))

(tcp/start-server echo-handler {:port 10001})

A TCP client can be created via (aleph.tcp/client {:host "example.com", :port 10001}), which returns a deferred which yields a duplex stream.

To learn more, read the example code.

UDP

A UDP socket can be generated using (aleph.udp/socket {:port 10001, :broadcast? false}). If the :port is specified, it will yield a duplex socket which can be used to send and receive messages, which are structured as maps with the following data:

{:host "example.com"
 :port 10001
 :message ...}

Where incoming packets will have a :message that is a byte-array, which can be coerced using byte-streams, and outgoing packets can be any data which can be coerced to a binary representation. If no :port is specified, the socket can only be used to send messages.

To learn more, read the example code.

Development

Aleph uses Leiningen for managing dependencies, running REPLs and tests, and building the code.

Minimal tools.deps support is available in the form of a deps.edn file which is generated from project.clj. It provides just enough to be able to use Aleph as a git or :local/root dependency. When committing changes to project.clj, run deps/lein-to-deps and commit the resulting changes, too.

License

Copyright © 2010-2023 Zachary Tellman

Distributed under the MIT License

About

Asynchronous communication for Clojure

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages

  • Clojure 99.2%
  • Java 0.8%