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An LFE Wrapper for the Erlang RabbitMQ (AMQP) Client

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kanin

Build Status LFE Versions Erlang Versions Tags Downloads

An LFE Wrapper for the Erlang RabbitMQ (AMQP) Client

Table of Contents

Introduction

The kanin library is a wrapper for various modules in the Erlang AMQP client library. kanin was created in order to not only provide a less verbose AMQP client library for LFE hackers, but one that was also more Lispy.

Installation

To pull in kanin as part of your project, just add it to your rebar.config deps:

  {deps, [
    ...
    {kanin, {git, "git@github.com:lfex/kanin.git", {branch, "master"}}}
  ]}.

And then do:

    $ rebar3 compile

Documentation

Below, in the "Usage" section, you will find information about using Kanin with RabbitMQ in LFE projects.

Also, you may be interested in the Kanin tutorials, which have been translated into LFE from the official RabbitMQ docs for Python and Erlang.

Supported Modules

The following amqp_* modules have been included in kanin:

  • amqp_channel -> kanin-chan
  • amqp_connection -> kanin-conn
  • amqp_uri -> kanin-uri

If your favorite amqp_* module is not among those, feel free to submit a new ticket requesting the addition of your desired module(s) or submit a pull request with the desired inclusion added.

Usage

Copyright Notice

The following content was copied from the Erlang Client User Guide on the RabbitMQ site. The original copyright was in 2014, held by Pivotal Software, Inc.

The LFE AMQP Client Library

The AMQP client provides an Erlang interface to compliant AMQP brokers. The client follows the AMQP execution model and implements the wire level marshaling required to encode and decode AMQP commands in a protocol conformant fashion. AMQP is a connection orientated protocol and multiplexes parallel interactions via multiple channels within a connection.

This user guide assumes that the reader is familiar with basic concepts of AMQP and understands exchanges, queues and bindings. This information is contained in the protocol documentation on the AMQP website. For details and exact definitions, please see the AMQP specification document.

The basic usage of the client follows these broad steps:

  • Establish a connection to a broker
  • Create a new channel within the open connection
  • Execute AMQP commands with a channel such as sending and receiving messages, creating exchanges and queue or defining routing rules between exchanges and queues
  • When no longer required, close the channel and the connection

Programming Model

Once a connection has been established, and a channel has been opened, an LFE application will typically use the kanin-chan:call/{2,3} and kanin-chan:cast/{2,3} functions to achieve most of the things it needs to do.

The underlying Erlang AMQP client library is made up of two layers:

  • A high level logical layer that follows the AMQP execution model, and
  • A low level driver layer that is responsible for providing a physical transport to a broker.

There are two drivers in the client library:

  • The network driver establishes a TCP connection to a protocol compliant AMQP broker and encodes each command according to the specification. To use this driver, start a connection using kanin-conn:start/1 with the parameter set to an #amqp_params_network record.

  • The direct driver uses native Erlang messaging instead of sending AMQP encoded commands over TCP. This approach avoids the overhead of marshaling commands onto and off the wire. However, the direct driver can only be used in conjunction with the RabbitMQ broker and the client code must be deployed into the same Erlang cluster. To use the direct driver, start a connection using kanin-conn:start/1 with the parameter set to an #amqp_params_direct record.

At run-time, the Erlang client library re-uses a subset of the functionality from the RabbitMQ broker. In order to keep the a client deployment independent of RabbitMQ, the Erlang client build process produces an archive containing all of the common modules. This archive is then put onto the load path of the client application.

For more detailed information on the API, please refer to the reference documentation.

Furthermore, the test suite that is part of the source distribution of the client library contains many complete examples of how to program against the API.

AMQP Commands

The general mechanism of interacting with the broker is to send and receive AMQP commands that are defined in the protocol documentation. During build process, the machine-readable version of the AMQP specification is used to auto-generate Erlang records for each command. The code generation process also defines sensible default values for each command. Using default values allows the programmer to write terser code - it is only necessary to override a field if you require non-default behaviour. The definition of each command can be consulted in the include/rabbit-framing.lfe header file. For example, when using the (make-exchange.declare ...) record-creating macro, specifying the following:

(make-exchange.declare exchange #"my_exchange")

is equivalent to this:

(make-exchange.declare
  exchange #"my_exchange"
  ticket 0
  type #"direct"
  passive 'false
  durable 'false
  auto_delete 'false
  internal 'false
  nowait 'false
  arguments '())

Including Header Files

The LFE client uses a number of record definitions which you will encounter in this guide. These records fall into two broad categories:

  • Auto-generated AMQP command definitions from the machine readable version of the specification
  • Definitions of data structures that are commonly used throughout the client

To gain access to these records, you need to include the amqp-client.lfe file in every module that uses the Erlang client:

(include-lib "kanin/include/amqp-client.lfe")

Connecting to a Broker

The kanin-conn module is used to start a connection to the broker. It requires either a direction connection options record or a network connection options record. These may be generated either by creating the records directly or providing connection information in a URI and having those parsed to generate the record for you.

Example optoins from record-creation:

lfe> (make-amqp_params_direct)
#(amqp_params_direct none none #"/" nonode@nohost none ())

and

lfe> (make-amqp_params_network host "localhost")
#(amqp_params_network
  #"guest"
  #"guest"
  #"/"
  "localhost"
  undefined 0 0 0 infinity none
  (#Fun<amqp_auth_mechanisms.plain.3> #Fun<amqp_auth_mechanisms.amqplain.3>)
  () ())

Example options from URI-parsing:

lfe> (kanin-uri:parse "amqp://dave:secret@")
#(ok #(amqp_params_direct #"dave" #"secret" #"/" nonode@nohost none ()))

and

lfe> (kanin-uri:parse "amqp://alice:secret@host:10000/vhost")
#(ok
  #(amqp_params_network
    #"alice"
    #"secret"
    #"vhost"
    "host"
    10000 0 0 10 infinity none
    (#Fun<amqp_uri.11.121287672> #Fun<amqp_uri.11.121287672>)
    () ()))

(For more information in this, see the section below: "Connecting To A Broker with AMQP URIs".)

To use these options to create an actual connection, use the kanin-conn module:

lfe> (set `#(ok ,net-opts) (kanin-uri:parse "amqp://localhost"))
lfe> (set `#(ok ,conn) (kanin-conn:start net-opts))

That's in the REPL; in an application using kanin, you'd want to use something like a (let ...) statement.

The ksnin-conn:start function returns #(ok ,conn), where conn is the pid of a process that maintains a permanent connection to the broker.

In case of an error, the above call returns #(error ,error).

The example above has just "localhost" as a parameter. However, there will often be many more than that.

An AMQP broker contains objects organised into groups called virtual hosts. The concept of virtual hosts gives an administrator the facility to partition a broker resource into separate domains and restrict access to the objects contained within these groups. AMQP connections require client authentication and the authorisation to access specific virtual hosts.

The (make-amqp_params_network) record macro sets the following default values:

Parameter Default Value
username guest
password guest
virtual_host /
host localhost
post 5672
channel_max 0
frame_max 0
heartbeat 0
ssl_options none
auth_mechanisms (list #'amqp_auth_mechanisms:plain/3 #'amqp_auth_mechanisms:amqplain/3)
client_properties '()

These values are only the defaults that will work with an out of the box broker running on the same host. If the broker or the environment has been configured differently, these values can be overridden to match the actual deployment scenario.

SSL options can also be specified globally using the ssl_options environment key for the amqp-client application. They will be merged with the SSL parameters from the URI (the latter will take precedence).

If a client wishes to run inside the same Erlang cluster as the RabbitMQ broker, it can start a direct connection that optimises away the AMQP codec. To start a direct connection, use kanin-conn:start/1 with the parameter set to an (make-amqp_params_direct) record.

Providing a username and password is optional, since the direct client is considered trusted anyway. If a username and password are provided then they will be checked and made available to authentication backends. If a username is supplied, but no password, then the user is considered trusted and logged in unconditionally. If neither username nor password are provided then the connection will be considered to be from a "dummy" user which can connect to any virtual host and issue any AMQP command.

The (make-amqp_params_direct) record macro sets the following default values:

Parameter Default Value
username #"guest"
password #"guest"
virtual_host #"/"
node (node)
client_properties '()

Connecting To A Broker with AMQP URIs

Instead of working the (make-amqp_params_*) records directly, AMQP URIs may be used. The (kanin-uri:parse/1) function is provided for this purpose. It parses an URI and returns the equivalent amqp_params_* record. Diverging from the spec, if the hostname is omitted, the connection is assumed to be direct and an amqp_params_direct record is returned. In addition to the standard host, port, user, password and vhost parameters, extra parameters may be specified via the query string (e.g. "?heartbeat=5").

AMQP URIs are defined with the following ABNF rules:

amqp_URI       = "amqp://" amqp_authority [ "/" vhost ] [ "?" query ]
amqp_authority = [ amqp_userinfo "@" ] host [ ":" port ]
amqp_userinfo  = username [ ":" password ]
username       = *( unreserved / pct-encoded / sub-delims )
password       = *( unreserved / pct-encoded / sub-delims )
vhost          = segment

Here are some examples:

Parameter Username Password Host Port Vhost
amqp://alice:secret@host:10000/vhost "alice" "secret" "host" 10000 "vhost"
amqp://bo%62:%73ecret@h%6fst:10000/%76host "bob" "secret" "host" 10000 "vhost"
amqp://
amqp://:@/ "" "" ""
amqp://carol@ "carol"
amqp://dave:secret@ "dave" "secret"
amqp://host "host"
amqp://:10000 10000
amqp:///vhost "vhost"
amqp://host/ "host" ""
amqp://host/%2f "host" "/"
amqp://[::1] "[::1]"

Using a connection URI, you can creat either direct or network connection options, and then use those to connect via the kanin-conn:start function (as demonstrated above).

Creating Channels

Once a connection to the broker has been established, the kanin-conn module can be used to create channels:

lfe> (set `#(ok ,chan) (kanin-conn:open-channel conn))
#(ok <0.114.0>)

This function takes the pid of the connection process and returns #(ok, chan), where chan is a pid that encapsulates a server side channel.

Managing Exchanges and Queues

Once a channel has been established, the kanin-chan module can be used to manage the fundamental objects within AMQP, namely exchanges and queues. The following function creates an exchange called my-exchange, which by default, is the direct exchange:

lfe> (set declare (make-exchange.declare exchange #"my-exchange"))
#(exchange.declare 0 #"my-exchange" #"direct" false false false false false ())
lfe> (kanin-chan:call chan declare)
#(exchange.declare_ok)

Similarly, a queue called my-queue is created by this code:

lfe> (set declare (make-queue.declare queue #"my-queue"))
#(queue.declare 0 #"my-queue" false false false false false ())
lfe> (kanin-chan:call chan declare)
#(queue.declare_ok #"my-queue" 0 0)

In many scenarios, a client is not interested in the actual name of the queue it wishes to receive messages from. In this case, it is possible to let the broker generate a random name for a queue. To do this, send a queue.declare command and leave the queue attribute undefined:

lfe> (kanin-chan:call chan (make-queue.declare))
#(queue.declare_ok #"amq.gen-nQEU2b7bjcGEi39TsYxXcg" 0 0)

The server will auto-generate a queue name and return this name as part of the acknowledgement.

To create a routing rule from an exchange to a queue, the queue.bind command is used:

lfe> (set binding (make-queue.bind queue #"my-queue"
                                   exchange #"my-exchange"
                                   routing_key #"my-key"))
#(queue.bind 0 #"my-queue" #"my-exchange" #"my-key" false ())
lfe> (kanin-chan:call chan binding)
#(queue.bind_ok)

When this routing rule is no longer required, this route can be deleted using the queue.unbind command:

lfe> (set binding (make-queue.unbind queue #"my-queue"
                                     exchange #"my-exchange"
                                     routing_key #"my-key"))
#(queue.unbind 0 #"my-queue" #"my-exchange" #"my-key" ())
lfe> (kanin-chan:call chan binding)
#(queue.unbind_ok)

An exchange can be deleted by the exchange.delete command:

lfe> (set delete (make-exchange.delete exchange #"my-exchange"))
#(exchange.delete 0 #"my-exchange" false false)
lfe> (kanin-chan:call chan delete)
#(exchange.delete_ok)

Similarly, a queue is deleted using the queue.delete command:

lfe> (set delete (make-queue.delete queue #"my-queue"))
#(queue.delete 0 #"my-queue" false false false)
lfe> (kanin-chan:call chan delete)
#(queue.delete_ok 0)

Note that we used kanin-chan:call/2 in the examples above, since we sent AMQP synchronous methods. It is generally advisable to use kanin- chan:call/{2,3} for synchronous methods, rather than kanin-chan:cast/{2,3}, even though both functions work with both sync and async method types. The difference between the two functions is that kanin-chan:call/{2,3} blocks the calling process until the reply comes back from the server (for sync methods) or the method has been sent on the wire (for async methods), whereas kanin-chan:cast/{2,3} returns ok immediately. Thus, only by using kanin- chan:call/{2,3} do we have direct feedback when the broker has acknowledged our command.

Sending Messages

To send a message to an exchange with a particular routing key, the basic.publish command in conjunction with the #amqp_msg{} record is used:

lfe> (set msg (make-amqp_msg payload #"foobar"))
#(amqp_msg
  #(P_basic ...)
  #"foobar")
lfe> (set pub (make-basic.publish exchange #"my-exchange" routing_key #"my-key"))
#(basic.publish 0 #"my-exchange" #"my-key" false false)
lfe> (kanin-chan:cast chan pub msg)
ok

By default, the properties field of the amqp_msg record contains a minimal implementation of the P_basic properties structure. If an application needs to override any of the defaults, for example, to send persistent messages, the amqp_msg needs to be constructed accordingly:

lfe> (set payload #"foobaz")
#"foobaz"
lfe> (set pub (make-basic.publish exchange #"my-exchange" routing_key #"my-key"))
#(basic.publish 0 #"my-exchange" #"my-key" false false)

Set persistent delivery mode property:

lfe> (set basic-properties (make-P_basic delivery_mode 2))
#(P_basic ... 2 ...)

Continue with message creation and send:

lfe> (set msg (make-amqp_msg props basic-properties payload #"foobar"))
#(amqp_msg
  #(P_basic ... 2 ...)
  #"foobar")
lfe> (kanin-chan:cast chan pub msg)
ok

The full list of message headers is explained in the AMQP protocol documentation.

Remember that the AMQP basic.publish command is asynchronous. This means that the server will not send a response to it, unless the message is not deliverable. In this case, the message will be returned to the client. This operation is described in the "Handling Returned Messages" section below.

Receiving Messages

The simplest way to receive a message is to poll an existing queue. This is achieved using the basic.get command:

lfe> (set get-cmd (make-basic.get queue #"my-queue" no_ack 'true))
#(basic.get 0 #"my-queue" true)
lfe> (set `#(,(= (match-basic.get_ok) ok) ,content) (kanin-chan:call chan get-cmd))
#(#(basic.get_ok ...)
  #(amqp_msg
    #(P_basic ...)
    #"foobar"))
lfe> ok
#(basic.get_ok ...)
lfe> content
#(amqp_msg
  #(P_basic ...)
  #"foobar")

The payload that is returned is an Erlang binary, and it is up to the application to decode it, as the structure of this content is opaque to the AMQP protocol.

If the queue was empty when the basic.get command was invoked, then the channel will return an basic.get_empty message, as illustrated here:

lfe> (set (= (match-basic.get_empty) content)
          (kanin-chan:call chan get-cmd))
#(basic.get_empty #"")
lfe> content
#(basic.get_empty #"")

Note that the previous example sets the no_ack flag on the basic.get command. This tells the broker that the receiver will not send an acknowledgement of the message. In doing so, the broker can absolve itself of the responsibility for delivery - once it believes it has delivered a message, then it is free to assume that consuming application has taken responsibility for it. In general, a lot of applications will not want these semantics, rather, they will want to explicitly acknowledge the receipt of a message. This is done with the basic.ack command, where the no_ack field is turned off by default:

lfe> (set get-cmd (make-basic.get queue #"my-queue"))
#(basic.get 0 #"my-queue" false)
lfe> (set `#(,(match-basic.get_ok delivery_tag msg-tag) ,content)
          (kanin-chan:call chan get-cmd))
#(...)
lfe> msg-tag
7

After the application has done what it needs to do with the response, it can acknowledge the message:

lfe> (kanin-chan:cast chan (make-basic.ack delivery_tag msg-tag))
ok

Notice that we sent the basic.ack command using kanin-chan:cast/2 instead of kanin-chan:call/2. This is because the broker will not send a response to an acknowledgement, i.e. it is a fire and forget command.

Receiving messages by polling a queue is not as as efficient as subscribing a consumer to a queue, so consideration should be taken when receiving large volumes of messages.

Subscribing to Queues

As indicated in the "Receiving Messages" section, subscribing to a queue can be a more efficient means of consuming messages than the polling mechanism. To subscribe to a queue, the basic.consume command is used in one of two forms:

lfe> (set sub (make-basic.consume queue #"my-queue"))
#(basic.consume 0 #"my-queue" #"" false false false false ())
lfe> (set (match-basic.consume_ok consumer_tag cnsm-tag)
          (kanin-chan:subscribe chan sub consumer-pid))

or

(set sub (make-basic.consume queue #"my-queue"))
#(basic.consume 0 #"my-queue" #"" false false false false ())
lfe> (set (match-basic.consume_ok consumer_tag cnsm-tag)
          (kanin-chan:call chan sub))
#(basic.consume_ok #"amq.ctag-QDTEY6V7duBFu_k86wayzg")
lfe> cnsm-tag
#"amq.ctag-QDTEY6V7duBFu_k86wayzg"

The consumer-pid argument is the pid of a process to which the client library will deliver messages. This can be an arbitrary Erlang process, including the process that initiated the subscription. The basic.consume_ok notification contains a tag that identifies the subscription. This is used at a later point in time to cancel the subscription. This notification is sent both to the process that created the subscription (as the return value to kanin-chan:subscribe/3) and as a message to the consumer process.

When a consumer process is subscribed to a queue, it will receive messages in its mailbox. An example receive loop looks like this:

(defun loop (chan)
  (receive
    ;; This is the first message received
    ((match-basic.consume_ok)
      (loop chan))
    ;; This is received when the subscription is cancelled
    ((match-basic.cancel_ok)
      'ok)
    ;; A delivery
    (`#(,(match-basic.deliver delivery_tag tag) ,content)
      ;; do somehting with the message payload here ...
      (lfe_io:format "Payload: ~p~n" `(,content))
      (kanin-chan:cast chan (make-basic.ack delivery_tag tag))
      (loop chan))))

In this simple example, the process consumes the subscription notification and then proceeds to wait for delivery messages to arrive in its mailbox. When messages are received from the mailbox, the loop does something useful with the message and sends a receipt acknowledge back to the broker. If the subscription is cancelled, either by the consumer itself or some other process, a cancellation notification will be sent to the consumer process. In this scenario, the receive loop just exits. If the application does not wish to explicitly acknowledge message receipts, it should set the no_ack flag on the subscription request.

To run the loop, spawn the function, subscribe the pid, and publish some messages:

lfe> (set consumer-pid (spawn (lambda () (loop chan))))
<0.141.0>
lfe> (kanin-chan:subscribe chan sub consumer-pid)
#(basic.consume_ok #"amq.ctag-wGk8K-6_YH-ovKODkDZQKA")
lfe> (kanin-chan:cast chan pub msg)
ok
Payload: #(amqp_msg
           #(P_basic ...)
           #"foobar")

To cancel a subscription, use the tag that the broker passed back with the basic.consume_ok acknowledgement:

lfe> (kanin-chan:call chan (make-basic.cancel consumer_tag tag))

Subscribing Internals

The channel uses a module implementing the amqp_gen_consumer behaviour to determine its behaviour with regard to subscribing related events. Effectively, this modules handles client-side consumer registration and routing of deliveries to the appropriate consumers.

For instance, the default consumer module, amqp_selective_consumer, keeps track of which processes are subscribed to which queues and routes deliveries appropriately; in addition, if the channel gives it a delivery for an unknown consumer, it will pass it to a default consumer, should one be registered.

By contrast, amqp_direct_consumer simply forwards all the messages it receives from the channel to its only registered consumer.

The consumer module for a channel is chosen when the channel is opened by setting the second parameter to kanin-conn:open-channel/2. The consumer module implements the amqp_gen_consumer behaviour and thus implements functions to handle receiving basic.consume, basic.consume_ok, basic.cancel, basic.cancel_ok methods as well as publishes.

See the API documentation for details.

Closing Channels and the Connection

When a channel is no longer required, a client should close it. This is achieved using kanin-chan:close/1:

lfe> (kanin-chan:close chan)
ok

To close the connection, kanin-conn:close/1 is used:

lfe> (kanin-conn:close conn)
ok

Both the channel.close and connection.close commands take the arguments reply_code (an integer) and reply_text (binary text), which can be set by the client depending on the reason why the channel or connection is being closed. In general, however, the reply_code is set to 200 to indicate a normal shutdown. The reply_text attribute is just an arbitrary string, that the server may or may not log. If a client wants to set to a different reply code and/or text, it can use the overloaded functions kanin-chan:close/3 and kanin-conn:close/3 respectively.

Complete Example

This shows a complete example:

(include-lib "ltest/include/ltest-macros.lfe")
(include-lib "kanin/include/amqp-client.lfe")

(defun example ()
  (let* (;; Get connection options
         (`#(ok ,opts) (kanin-uri:parse "amqp://localhost"))
         ;; Start a network connection
         (`#(ok ,conn) (kanin-conn:start opts))
         ;; Open a channel on the connection
         (`#(ok ,chan) (kanin-conn:open-channel conn))
         (example-exchange #"example-exchange")
         (example-queue #"example-queue")
         (example-key #"example-key"))
    ;; Declare an exchange
    (kanin-chan:call
      chan
      (make-exchange.declare
        exchange example-exchange))
    ;; Declare a queue
    (kanin-chan:call
      chan
      (make-queue.declare
        queue example-queue))
    ;; Bind an exchange and queue with a routing key
    (kanin-chan:call
      chan
      (make-queue.bind
        queue example-queue
        exchange example-exchange
        routing_key example-key))
    ;; Publish a message
    (let ((msg (make-amqp_msg payload #"foobar"))
          (pub (make-basic.publish
                 exchange example-exchange
                 routing_key example-key)))
      (kanin-chan:cast chan pub msg))
    ;; Get the message back from the queue
    (let* ((get-cmd (make-basic.get queue example-queue))
          (`#(,(match-basic.get_ok delivery_tag tag)
              ,(match-amqp_msg payload msg-payload))
            (kanin-chan:call chan get-cmd)))
      ;; Do something with the message payload
      (io:format "~nGot message: ~p~n" `(,msg-payload))
      ;; Ack the message
      (kanin-chan:cast chan (make-basic.ack delivery_tag tag)))
    ;; Close the channel
    (kanin-chan:close chan)
    ;; Close the connection
    (kanin-conn:close conn)))

To run from the LFE REPL, simply paste the above, and then run (example).

In the example above, we created an exchange and queue, and bound the the two. We then created a message and published it to the exchange. The message was then dequeued and acknowledged.

Delivery Flow Control

By default, there is no flow control within a channel other than normal TCP back-pressure. A consumer can set the size of the prefetch buffer that the broker will maintain for outstanding unacknowledged messages on a single channel. This is achieved using the basic.qos command:

lfe> (kanin-chan:call
       chan
       (make-basic.qos prefetch_count prefetch))

Applications typically should set the prefetch count, which means the processing speed of the consumer will exert back-pressure on the flow of messages in that channel.

Blocked Connections

When an AMQP broker is running low on resources, for example by hitting a memory high watermark, it may choose to stop reading from publishers' network sockets.

RabbitMQ introduces a mechanism to allow clients to be told this has taken place - invoke kanin-conn:register-blocked-handler/2 giving the pid of a process to which (make-connection.blocked) and (make-connection.unblocked) messages may be sent.

Handling Returned Messages

The broker will return undeliverable messages back to the originating client. These are messages published either with the immediate or mandatory flags set. In order for the application to get notified of a return, it must register a callback process that can process (make-basic.return) commands. Here is an example of unrouteable message:

(kanin-chan:register-return-handler chan (self))
(kanin-chan:call
  chan
  (make-exchange.declare exchange some-name))
(let ((pub (make-basic.publish
             exchange some-name
             routing_key some-key
             mandatory 'true)))
  (kanin-chan:call chan pub (make-amqp_msg payload #"some payload"))
  (receive
    (`#(,(match-basic.return reply_text #"unroutable" exchange some-name)
        ,content)
      ;; Do something with the returned message
      ...)))
      (make-basic.return )))))

License

Apache License, Version 2.0

Copyright © 2014-2017, BilloSystems, Ltd. Co.

Copyright © 2015-2017, Ricardo Lanziano

Copyright © 2015-2017, Duncan McGreggor

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