Working with queues
About this guide
This guide covers everything related to queues in the AMQP v0.9.1 specification, common usage scenarios and how to accomplish typical operations using the amqp gem. This work is licensed under a Creative Commons Attribution 3.0 Unported License (including images and stylesheets). The source is available on Github.
Which versions of the amqp gem does this guide cover?
This guide covers Ruby amqp gem 1.7.0 and later versions.
Queues in AMQP 0.9.1 - overview
What are AMQP queues?
Queues store and forward messages to consumers. They are similar to mailboxes in SMTP. Messages flow from producing applications to exchanges that route them to queues and finally queues deliver the messages to consumer applications (or consumer applications fetch messages as needed).
Note that unlike some other messaging protocols/systems, messages are not delivered directly to queues. They are delivered to exchanges that route messages to queues using rules known as bindings.
AMQP 0-9-1 is a programmable protocol, so queues and bindings alike are declared by applications.
Concept of bindings
A binding is an association between a queue and an exchange. Queues must be bound to at least one exchange in order to receive messages from publishers. Learn more about bindings in the Bindings guide.
Queue attributes
Queues have several attributes associated with them:
- Name
- Exclusivity
- Durability
- Whether the queue is auto-deleted when no longer used
- Other metadata (sometimes called X-arguments)
These attributes define how queues can be used, what their life-cycle is like and other aspects of queue behavior.
The amqp gem represents queues as instances of AMQP::Queue.
Queue names and declaring queues
Every AMQP queue has a name that identifies it. Queue names often contain several segments separated by a dot “.”, in a similar fashion to URI path segments being separated by a slash “/”, although almost any string can represent a segment (with some limitations - see below).
Before a queue can be used, it has to be declared. Declaring a queue will cause it to be created if it does not already exist. The declaration will have no effect if the queue does already exist and its attributes are the same as those in the declaration. When the existing queue attributes are not the same as those in the declaration a channel-level exception is raised. This case is explained later in this guide.
Explicitly named queues
Applications may pick queue names or ask the broker to generate a name for them.
To declare a queue with a particular name, for example, “images.resize”, pass it to the Queue class constructor:
queue = AMQP::Queue.new(channel, "images.resize", :auto_delete => true)
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
# Declaring a queue with explicitly given name using AMQP::Queue constructor
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
queue = AMQP::Queue.new(channel, "images.resize", :auto_delete => true)
puts "#{queue.name} is ready to go."
connection.close {
EventMachine.stop { exit }
}
end
Server-named queues
To ask an AMQP broker to generate a unique queue name for you, pass an empty string as the queue name argument:
AMQP::Queue.new(channel, "", :auto_delete => true) do |queue, declare_ok|
puts "#{queue.name} is ready to go. AMQP method: #{declare_ok.inspect}"
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
# Declaring a queue with server-generated name using AMQP::Queue constructor
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
AMQP::Queue.new(channel, "", :auto_delete => true) do |queue|
puts "#{queue.name} is ready to go."
connection.close {
EventMachine.stop { exit }
}
end
end
The amqp gem allows server-named queues to be declared without callbacks:
queue = AMQP::Queue.new(channel, "", :auto_delete => true)
In this case, as soon as the AMQP broker reply (queue.declare-ok
AMQP method) arrives, the queue object name will be assigned to the
value that the broker generated. Many AMQP operations require a queue
name, so before an AMQP::Queue instance receives its
name, those operations are delayed. This example demonstrates this:
queue = channel.queue("")
queue.bind("builds").subscribe do |metadata, payload|
# message handling implementation...
end
In this example, binding will be performed as soon as the queue has received its name generated by the broker.
If a particular piece of code relies on the queue name being available immediately a callback should be used.
Reserved queue name prefix
Queue names starting with “amq.” are reserved for internal use by the
broker. Attempts to declare a queue with a name that violates this rule
will result in a channel-level exception with reply code 403
(ACCESS_REFUSED) and a reply message similar to this:
ACCESS_REFUSED - queue name ‘amq.queue’ contains reserved prefix
’amq.**‘
Queue re-declaration with different attributes
When queue declaration attributes are different from those that the
queue already has, a channel-level exception with code 406
(PRECONDITION_FAILED) will be raised. The reply text will be similar to
this:
PRECONDITION_FAILED - parameters for queue
’amqpgem.examples.channel_exception’ in vhost ‘/’ not equivalent
Queue life-cycle patterns
According to the AMQP 0.9.1 specification, there are two common message queue life-cycle patterns:
- Durable message queues that are shared by many consumers and have an independent existence: i.e. they will continue to exist and collect messages whether or not there are consumers to receive them.
- Temporary message queues that are private to one consumer and are tied to that consumer. When the consumer disconnects, the message queue is deleted.
There are some variations of these, such as shared message queues that are deleted when the last of many consumers disconnects.
Let us examine the example of a well-known service like an event collector (event logger). A logger is usually up and running regardless of the existence of services that want to log anything at a particular point in time. Other applications know which queues to use in order to communicate with the logger and can rely on those queues being available and able to survive broker restarts. In this case, explicitly named durable queues are optimal and the coupling that is created between applications is not an issue.
Another example of a well-known long-lived service is a distributed metadata/directory/locking server like Apache Zookeeper, etcd or DNS. Services like this benefit from using well-known, not server-generated, queue names and so do any other applications that use them.
A different sort of scenario is in “a cloud setting” when some kind of worker/instance might start and stop at any time so that other applications cannot rely on it being available. In this case, it is possible to use well-known queue names, but a much better solution is to use server-generated, short-lived queues that are bound to topic or fanout exchanges in order to receive relevant messages.
Imagine a service that processes an endless stream of events - Twitter is one example. When traffic increases, development operations may start additional application instances in the cloud to handle the load. Those new instances want to subscribe to receive messages to process, but the rest of the system does not know anything about them and cannot rely on them being online or try to address them directly. The new instances process events from a shared stream and are the same as their peers. In a case like this, there is no reason for message consumers not to use queue names generated by the broker.
In general, use of explicitly named or server-named queues depends on the messaging pattern that your application needs. Enterprise Integration Patterns discusses many messaging patterns in depth and the RabbitMQ FAQ also has a section on use cases.
Declaring a durable shared queue
To declare a durable shared queue, you pass a queue name that is a
non-blank string and use the :durable option:
queue = AMQP::Queue.new(channel, "images.resize", :durable => true)
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
# Declaring a durable shared queue
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
queue = AMQP::Queue.new(channel, "images.resize", :durable => true)
connection.close {
EventMachine.stop { exit }
}
end
the same example rewritten to use AMQP::Channel#queue:
channel.queue("images.resize", :durable => true) do |queue, declare_ok|
puts "#{queue.name} is ready to go."
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
# Declaring a durable shared queue using AMQP::Channel#queue method
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
queue = channel.queue("images.resize", :durable => true)
connection.close {
EventMachine.stop { exit }
}
end
Declaring a temporary exclusive queue
To declare a server-named, exclusive, auto-deleted queue, pass "" (an empty
string) as the queue name and use the ](exclusive") and :auto_delete
options:
AMQP::Queue.new(channel, "", :auto_delete => true, :exclusive => true) do |queue, declare_ok|
puts "#{queue.name} is ready to go."
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
# Declaring a temporary exclusive queue
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
AMQP::Queue.new(channel, "", :auto_delete => true, :exclusive => true) do |queue, declare_ok|
puts "#{queue.name} is ready to go."
connection.close {
EventMachine.stop { exit }
}
end
end
The same example can be rewritten to use
AMQP::Channel#queue:
channel.queue("", :auto_delete => true, :exclusive => true) do |queue, declare_ok|
puts "#{queue.name} is ready to go."
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
# Declaring a temporary exclusive queue
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
AMQP::Channel.new do |channel, open_ok|
channel.queue("", :auto_delete => true, :exclusive => true) do |queue, declare_ok|
puts "#{queue.name} is ready to go."
connection.close {
EventMachine.stop { exit }
}
end
end
end
Exclusive queues may only be accessed by the current connection and are
deleted when that connection closes. The declaration of an exclusive
queue by other connections is not allowed and will result in a
channel-level exception with the code 405 (RESOURCE_LOCKED) and a reply
message similar to
require "rubygems"
require 'amqp'
puts "=> Queue exclusivity violation results "
puts
EventMachine.run do
connection1 = AMQP.connect("amqp://guest:guest@dev.rabbitmq.com")
channel1 = AMQP::Channel.new(connection1)
connection2 = AMQP.connect("amqp://guest:guest@dev.rabbitmq.com")
channel2 = AMQP::Channel.new(connection2)
channel1.on_error do |ch, close|
puts "Handling a channel-level exception on channel1: #{close.reply_text}, #{close.inspect}"
end
channel2.on_error do |ch, close|
puts "Handling a channel-level exception on channel2: #{close.reply_text}, #{close.inspect}"
end
name = "amqpgem.examples.queue"
channel1.queue(name, :auto_delete => true, :exclusive => true)
# declare a queue with the same name on a different connection
channel2.queue(name, :auto_delete => true, :exclusive => true)
EventMachine.add_timer(3.5) do
connection1.close {
connection2.close {
EventMachine.stop { exit }
}
}
end
end
Binding queues to exchanges
In order to receive messages, a queue needs to be bound to at least one
exchange. Most of the time binding is explcit (done by applications). To
bind a queue to an exchange, use AMQP::Queue#bind where
the argument passed can be either an AMQP::Exchange
instance or a string.
queue.bind(exchange) do |bind_ok|
puts "Just bound #{queue.name} to #{exchange.name}"
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
# Binding a queue to an exchange
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
exchange = channel.fanout("amq.fanout")
channel.queue("", :auto_delete => true, :exclusive => true) do |queue, declare_ok|
queue.bind(exchange) do |bind_ok|
puts "Just bound #{queue.name} to #{exchange.name}"
end
connection.close {
EventMachine.stop { exit }
}
end
end
The same example using a string without callback:
queue.bind("amq.fanout")
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
# Binding a queue to an exchange
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
exchange_name = "amq.fanout"
channel.queue("", :auto_delete => true, :exclusive => true) do |queue, declare_ok|
queue.bind(exchange_name)
puts "Bound #{queue.name} to #{exchange_name}"
connection.close {
EventMachine.stop { exit }
}
end
end
Subscribing to receive messages (“push API”)
To set up a queue subscription to enable an application to receive
messages as they arrive in a queue, one uses the
AMQP::Queue#subscribe method. Then when a message
arrives, the message header (metadata) and body (payload) are passed to
the handler:
queue.subscribe do |metadata, payload|
puts "Received a message: #{payload.inspect}."
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
exchange = channel.fanout("amq.fanout")
channel.queue("", :auto_delete => true, :exclusive => true) do |queue|
queue.bind(exchange).subscribe do |metadata, payload|
puts "Received a message: #{payload.inspect}. Shutting down..."
connection.close { EventMachine.stop }
end
EventMachine.add_timer(0.2) do
puts "=> Publishing..."
exchange.publish("Ohai!")
end
end
end
Subscriptions for message delivery are usually referred to as consumers in the AMQP 0.9.1 specification, client library documentation and books. Consumers last as long as the channel that they were declared on, or until client cancels them (unsubscribes).
Consumers are identified by consumer tags. If
you need to obtain the consumer tag of a subscribed queue then use
AMQP::Queue#consumer_tag.
Accessing message metadata
The header object in the example above provides access to message metadata and delivery information:
- Message content type
- Message content encoding
- Message routing key
- Message delivery mode (persistent or not)
- Consumer tag this delivery is for
- Delivery tag
- Message priority
- Whether or not message is redelivered
- Producer application id
and so on. An example to demonstrate how to access some of those attributes:
# producer
exchange.publish("Hello, world!",
:app_id => "amqpgem.example",
:priority => 8,
:type => "kinda.checkin",
# headers table keys can be anything
:headers => {
:coordinates => {
:latitude => 59.35,
:longitude => 18.066667
},
:participants => 11,
:venue => "Stockholm"
},
:timestamp => Time.now.to_i)
# consumer
queue.subscribe do |metadata, payload|
puts "metadata.routing_key : #{metadata.routing_key}"
puts "metadata.content_type: #{metadata.content_type}"
puts "metadata.priority : #{metadata.priority}"
puts "metadata.headers : #{metadata.headers.inspect}"
puts "metadata.timestamp : #{metadata.timestamp.inspect}"
puts "metadata.type : #{metadata.type}"
puts "metadata.delivery_tag: #{metadata.delivery_tag}"
puts "metadata.redelivered : #{metadata.redelivered?}"
puts "metadata.app_id : #{metadata.app_id}"
puts "metadata.exchange : #{metadata.exchange}"
puts
puts "Received a message: #{payload}."
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "bundler"
Bundler.setup
$:.unshift(File.expand_path("../../../lib", __FILE__))
require 'amqp'
EventMachine.run do
connection = AMQP.connect(:host => '127.0.0.1')
puts "Connected to AMQP broker. Running #{AMQP::VERSION} version of the gem..."
channel = AMQP::Channel.new(connection)
queue = channel.queue("amqpgem.examples.hello_world", :auto_delete => true)
exchange = channel.direct("amq.direct")
queue.bind(exchange)
channel.on_error do |ch, channel_close|
puts channel_close.reply_text
connection.close { EventMachine.stop }
end
queue.subscribe do |metadata, payload|
puts "metadata.routing_key : #{metadata.routing_key}"
puts "metadata.content_type: #{metadata.content_type}"
puts "metadata.priority : #{metadata.priority}"
puts "metadata.headers : #{metadata.headers.inspect}"
puts "metadata.timestamp : #{metadata.timestamp.inspect}"
puts "metadata.type : #{metadata.type}"
puts "metadata.delivery_tag: #{metadata.delivery_tag}"
puts "metadata.redelivered : #{metadata.redelivered}"
puts "metadata.app_id : #{metadata.app_id}"
puts "metadata.exchange : #{metadata.exchange}"
puts
puts "Received a message: #{payload}. Disconnecting..."
connection.close {
EventMachine.stop { exit }
}
end
exchange.publish("Hello, world!",
:app_id => "amqpgem.example",
:priority => 8,
:type => "kinda.checkin",
# headers table keys can be anything
:headers => {
:coordinates => {
:latitude => 59.35,
:longitude => 18.066667
},
:participants => 11,
:venue => "Stockholm"
},
:timestamp => Time.now.to_i)
end
Exclusive consumers
Consumers can request exclusive access to the queue (meaning only this consumer can access the queue). This is useful when you want a long-lived shared queue to be temporarily accessible by just one application (or thread, or process). If the application employing the exclusive consumer crashes or loses the TCP connection to the broker, then the channel is closed and the exclusive consumer is cancelled.
To exclusively receive messages from the queue, pass the “:exclusive”
option to AMQP::Queue#subscribe:
queue.subscribe(:exclusive => true) do |metadata, payload|
# message handling logic...
end
TBD: describe what happens when exclusivity property is violated and how to handle it.
Using multiple consumers per queue
Historically, amqp gem versions before 0.8.0.RC14 (current master branch in the repository) have had a “one consumer per Queue instance” limitation. Previously, to work around this problem, application developers had to open multiple channels and work with multiple queue instances on different channels. This is not very convenient and is surprising for developers familiar with AMQP clients for other languages.
With more and more Ruby implementations dropping the GIL, load balancing between multiple consumers in the same queue in the same OS process has become more and more common. In certain cases, even applications that do not need any concurrency benefit from having multiple consumers on the same queue in the same process.
Starting from amqp gem 0.8.0, it is possible to add any number of
consumers by instantiating AMQP::Consumer directly:
# non-exclusive consumer, consumer tag is generated
consumer1 = AMQP::Consumer.new(channel, queue)
# non-exclusive consumer, consumer tag is explicitly given
consumer2 = AMQP::Consumer.new(channel, queue, "#{queue.name}-consumer-#{rand}-#{Time.now}")
# exclusive consumer, consumer tag is generated
consumer3 = AMQP::Consumer.new(channel, queue, nil, true)
Instantiated consumers do not begin consuming messages immediately. This
is because in certain cases, it is useful to add a consumer but make it
active at a later time. To consume messages, use the
AMQP::Consumer#consume method in combination with
AMQP::Consumer#on_delivery:
consumer1.consume.on_delivery do |metadata, payload|
@consumer1_mailbox << payload
end
AMQP::Consumer#on_delivery takes a block that is used
exactly like the block passed to AMQP::Queue#subscribe.
In fact, AMQP::Queue#subscribe uses
AMQP::Consumer under the hood, adding a
default consumer to the queue.
Default consumers do not have any special properties, they just provide a convenient way for application developers to register multiple consumers and a means of preserving backwards compatibility. Application developers are always free to use `AMQP::Consumer` instances directly, or intermix them with `AMQP::Queue#subscribe`.
Most of the public API methods on AMQP::Consumer return
self, so it is possible to use method chaining extensively. An example
from amqp gem spec
suite:
consumer1 = AMQP::Consumer.new(@channel, @queue).consume.on_delivery { |metadata, payload| mailbox1 << payload }
consumer2 = AMQP::Consumer.new(@channel, @queue).consume.on_delivery { |metadata, payload| mailbox2 << payload }
To cancel a particular consumer, use
AMQP::Consumer#cancel method. To cancel a default queue
consumer, use AMQP::Queue#unsubscribe.
Message acknowledgements
Consumer applications - applications that receive and process messages - may occasionally fail to process individual messages, or will just crash. There is also the possibility of network issues causing problems. This raises a question - “When should the AMQP broker remove messages from queues?” The AMQP 0.9.1 specification proposes two choices:
- After broker sends a message to an application (using either basic.deliver or basic.get-ok methods).
- After the application sends back an acknowledgement (using basic.ack AMQP method).
The former choice is called the automatic acknowledgement model, while the latter is called the explicit acknowledgement model. With the explicit model, the application chooses when it is time to send an acknowledgement. It can be right after receiving a message, or after persisting it to a data store before processing, or after fully processing the message (for example, successfully fetching a Web page, processing and storing it into some persistent data store).
If a consumer dies without sending an acknowledgement, the AMQP broker will redeliver it to another consumer, or, if none are available at the time, the broker will wait until at least one consumer is registered for the same queue before attempting redelivery.
The acknowledgement model is chosen when a new consumer is registered
for a queue. By default, AMQP::Queue#subscribe will use
the automatic model. To switch to the explicit model, the “:ack”
(for "manual ack") option should be used:
queue.subscribe(:ack => true) do |metadata, payload|
# message handling logic...
end
To demonstrate how redelivery works, let us have a look at the following code example:
#!/usr/bin/env ruby
# encoding: utf-8
require "bundler"
Bundler.setup
$:.unshift(File.expand_path("../../../lib", __FILE__))
require 'amqp'
puts "=> Subscribing for messages using explicit acknowledgements model"
puts
# this example uses Kernel#sleep and thus we must run EventMachine reactor in
# a separate thread, or nothing will be sent/received while we sleep() on the current thread.
t = Thread.new { EventMachine.run }
sleep(0.5)
# open two connections to imitate two apps
connection1 = AMQP.connect
connection2 = AMQP.connect
connection3 = AMQP.connect
channel_exception_handler = Proc.new { |ch, channel_close| EventMachine.stop; raise "channel error: #{channel_close.reply_text}" }
# open two channels
# first app will be given up to 3 messages at a time. If it doesn't
# ack any messages after it was delivered 3, messages will be routed to
# the app #2.
channel1 = AMQP::Channel.new(connection1, :prefetch => 3)
channel1.on_error(&channel_exception_handler)
# app #2 processes messages one-by-one and has to send and ack every time
channel2 = AMQP::Channel.new(connection2, :prefetch => 1)
channel2.on_error(&channel_exception_handler)
# app 3 will just publish messages
channel3 = AMQP::Channel.new(connection3)
channel3.on_error(&channel_exception_handler)
exchange = channel3.direct("amq.direct")
queue1 = channel1.queue("amqpgem.examples.acknowledgements.explicit", :auto_delete => false)
# purge the queue so that we don't get any redeliveries from previous runs
queue1.purge
queue1.bind(exchange).subscribe(:ack => true) do |metadata, payload|
# do some work
sleep(0.2)
# acknowledge some messages, they will be removed from the queue
if rand > 0.5
# FYI: there is a shortcut, metadata.ack
channel1.acknowledge(metadata.delivery_tag, false)
puts "[consumer1] Got message ##{metadata.headers['i']}, ack-ed"
else
# some messages are not ack-ed and will remain in the queue for redelivery
# when app #1 connection is closed (either properly or due to a crash)
puts "[consumer1] Got message ##{metadata.headers['i']}, SKIPPPED"
end
end
queue2 = channel2.queue!("amqpgem.examples.acknowledgements.explicit", :auto_delete => false)
queue2.subscribe(:ack => true) do |metadata, payload|
metadata.ack
# app 2 always acks messages
puts "[consumer2] Received #{payload}, redelivered = #{metadata.redelivered}, ack-ed"
end
# after 2.5 seconds one of the consumers dies
EventMachine.add_timer(4.0) {
connection1.close
puts "----- Connection 1 is now closed (we pretend that it has crashed) -----"
}
EventMachine.add_timer(10.0) do
# purge the queue so that we don't get any redeliveries on the next run
queue2.purge {
connection2.close {
connection3.close { EventMachine.stop }
}
}
end
i = 0
EventMachine.add_periodic_timer(0.8) {
3.times do
exchange.publish("Message ##{i}", :headers => { :i => i })
i += 1
end
}
t.join
So what is going on here? This example uses three AMQP connections to imitate three applications, one producer and two consumers. Each AMQP connection opens a single channel:
# open multiple connections to imitate three apps
connection1 = AMQP.connect
connection2 = AMQP.connect
connection3 = AMQP.connect
channel_exception_handler = Proc.new { |ch, channel_close| EventMachine.stop; raise "channel error: #{channel_close.reply_text}" }
# open several channels
channel1 = AMQP::Channel.new(connection1)
channel1.on_error(&channel_exception_handler)
# ...
channel2 = AMQP::Channel.new(connection2)
channel2.on_error(&channel_exception_handler)
# ...
# app 3 will just publish messages
channel3 = AMQP::Channel.new(connection3)
channel3.on_error(&channel_exception_handler)
The consumers share a queue and the producer publishes messages to the
queue periodically using an amq.direct
exchange. Both “applications” subscribe to receive messages using the
explicit acknowledgement model. The AMQP broker by default will send
each message to the next consumer in sequence (this kind of load
balancing is known as round-robin). This means that some messages
will be delivered to consumer #1 and some to consumer #2.
exchange = channel3.direct("amq.direct")
# ...
queue1 = channel1.queue("amqpgem.examples.acknowledgements.explicit", :auto_delete => false)
# purge the queue so that we do not get any redeliveries from previous runs
queue1.purge
queue1.bind(exchange).subscribe(:ack => true) do |metadata, payload|
# do some work
sleep(0.2)
# acknowledge some messages, they will be removed from the queue
if rand > 0.5
# FYI: there is a shortcut, metadata.ack
channel1.acknowledge(metadata.delivery_tag, false)
puts "[consumer1] Got message ##{metadata.headers['i']}, ack-ed"
else
# odd messages are not ack-ed and will remain in the queue for redelivery
# when app #1 connection is closed (either properly or due to a crash)
puts "[consumer1] Got message ##{metadata.headers['i']}, SKIPPED"
end
end
queue2 = channel2.queue!("amqpgem.examples.acknowledgements.explicit", :auto_delete => false)
queue2.subscribe(:ack => true) do |metadata, payload|
metadata.ack
# app 2 always acks messages
puts "[consumer2] Received #{payload}, redelivered = #{metadata.redelivered}, ack-ed"
end
To demonstrate message redelivery we make consumer #1 randomly select which messages to acknowledge. After 4 seconds we disconnect it (to imitate a crash). When that happens, the AMQP broker redelivers unacknowledged messages to consumer #2 which acknowledges them unconditionally. After 10 seconds, this example closes all outstanding connections and exits.
An extract of output produced by this example:
=> Subscribing for messages using explicit acknowledgements
model
[consumer2] Received Message #0, redelivered = false, ack-ed
[consumer1] Got message #1, SKIPPED
[consumer1] Got message #2, SKIPPED
[consumer1] Got message #3, ack-ed
[consumer2] Received Message #4, redelivered = false, ack-ed
[consumer1] Got message #5, SKIPPED
[consumer2] Received Message #6, redelivered = false, ack-ed
[consumer2] Received Message #7, redelivered = false, ack-ed
[consumer2] Received Message #8, redelivered = false, ack-ed
[consumer2] Received Message #9, redelivered = false, ack-ed
[consumer2] Received Message #10, redelivered = false, ack-ed
[consumer2] Received Message #11, redelivered = false, ack-ed
—— Connection 1 is now closed (we pretend that it has crashed) ——
[consumer2] Received Message #5, redelivered = true, ack-ed
[consumer2] Received Message #1, redelivered = true, ack-ed
[consumer2] Received Message #2, redelivered = true, ack-ed
[consumer2] Received Message #12, redelivered = false, ack-ed
[consumer2] Received Message #13, redelivered = false, ack-ed
[consumer2] Received Message #14, redelivered = false, ack-ed
[consumer2] Received Message #15, redelivered = false, ack-ed
[consumer2] Received Message #16, redelivered = false, ack-ed
[consumer2] Received Message #17, redelivered = false, ack-ed
[consumer2] Received Message #18, redelivered = false, ack-ed
[consumer2] Received Message #19, redelivered = false, ack-ed
[consumer2] Received Message #20, redelivered = false, ack-ed
[consumer2] Received Message #21, redelivered = false, ack-ed
[consumer2] Received Message #22, redelivered = false, ack-ed
[consumer2] Received Message #23, redelivered = false, ack-ed
[consumer2] Received Message #24, redelivered = false, ack-ed
[consumer2] Received Message #25, redelivered = false, ack-ed
[consumer2] Received Message #26, redelivered = false, ack-ed
[consumer2] Received Message #27, redelivered = false, ack-ed
[consumer2] Received Message #28, redelivered = false, ack-ed
[consumer2] Received Message #29, redelivered = false, ack-ed
[consumer2] Received Message #30, redelivered = false, ack-ed
[consumer2] Received Message #31, redelivered = false, ack-ed
[consumer2] Received Message #32, redelivered = false, ack-ed
[consumer2] Received Message #33, redelivered = false, ack-ed
[consumer2] Received Message #34, redelivered = false, ack-ed
[consumer2] Received Message #35, redelivered = false, ack-ed
As we can see, consumer #1 did not acknowledge three messages (labelled 1, 2 and 5):
[consumer1] Got message #1, SKIPPED
[consumer1] Got message #2, SKIPPED
…
[consumer1] Got message #5, SKIPPED
and then, once consumer #1 had “crashed”, those messages were immediately redelivered to the consumer #2:
—— Connection 1 is now closed (we pretend that it has crashed) ——
[consumer2] Received Message #5, redelivered = true, ack-ed
[consumer2] Received Message #1, redelivered = true, ack-ed
[consumer2] Received Message #2, redelivered = true, ack-ed
To acknowledge a message use AMQP::Channel#acknowledge:
channel1.acknowledge(metadata.delivery_tag, false)
AMQP::Channel#acknowledge takes two arguments: message
delivery tag and a flag that indicates whether or not we want to
acknowledge multiple messages at once. Delivery tag is simply a
channel-specific increasing number that the server uses to identify
deliveries.
When acknowledging multiple messages at once, the delivery tag is treated as “up to and including”. For example, if delivery tag = 5 that would mean “acknowledge messages 1, 2, 3, 4 and 5”.
As a shortcut, it is possible to acknowledge messages using the
AMQP::Header#ack method:
queue2.subscribe(:ack => true) do |metadata, payload|
metadata.ack
end
Acknowledgements are channel-specific. Applications must not receive messages on one channel and acknowledge them on another.
A message MUST not be acknowledged more than once. Doing so will result in a channel-level exception (PRECONDITION_FAILED) with an error message like this: “PRECONDITION_FAILED - unknown delivery tag”
Rejecting messages
When a consumer application receives a message, processing of that message may or may not succeed. An application can indicate to the broker that message processing has failed (or cannot be accomplished at the time) by rejecting a message. When rejecting a message, an application can ask the broker to discard or requeue it.
To reject a message use the AMQP::Channel#reject method:
queue.bind(exchange).subscribe do |metadata, payload|
# reject but do not requeue (simply discard)
channel.reject(metadata.delivery_tag)
end
in the example above, messages are rejected without requeueing (broker
will simply discard them). To requeue a rejected message, use the second
argument that AMQP::Channel#reject takes:
queue.bind(exchange).subscribe do |metadata, payload|
# reject and requeue
channel.reject(metadata.delivery_tag, true)
end
When there is only one consumer on a queue, make sure you do not create infinite message delivery loops by rejecting and requeueing a message from the same consumer over and over again.
Another way to reject a message is by using AMQP::Header#reject:
queue.bind(exchange).subscribe do |metadata, payload|
# reject but do not requeue (simply discard)
metadata.reject
end
queue.bind(exchange).subscribe do |metadata, payload|
# reject and requeue
metadata.reject(:requeue => true)
end
Negative acknowledgements
Messages are rejected with the
basic.reject AMQP method. There is one
limitation that basic.reject has: there is
no way to reject multiple messages, as you can do with acknowledgements.
However, if you are using RabbitMQ, then there is
a solution. RabbitMQ provides an AMQP 0.9.1 extension known as negative
acknowledgements
(nacks) and the amqp gem supports this extension. For more information,
please refer to the Vendor-specific Extensions
guide.
QoS - Prefetching messages
For cases when multiple consumers share a queue, it is useful to be able to specify how many messages each consumer can be sent at once before sending the next acknowledgement. This can be used as a simple load balancing technique to improve throughput if messages tend to be published in batches. For example, if a producing application sends messages every minute because of the nature of the work it is doing.
Imagine a website that takes data from social media sources like Twitter or Facebook during the Champions League final (or the Superbowl), and then calculates how many tweets mention a particular team during the last minute. The site could be structured as 3 applications:
- A crawler that uses streaming APIs to fetch tweets/statuses,
normalizes them and sends them in JSON for processing by other
applications (“app A”).
- A calculator that detects what team is mentioned in a message, updates statistics and pushes an update to the Web UI once a minute (“app B”).
- A Web UI that fans visit to see the stats (“app C”).
In this imaginary example, the “tweets per second” rate will vary, but to improve the throughput of the system and to decrease the maximum number of messages that the AMQP broker has to hold in memory at once, applications can be designed in such a way that application “app B”, the “calculator”, receives 5000 messages and then acknowledges them all at once. The broker will not send message 5001 unless it receives an acknowledgement.
In AMQP 0.9.1 parlance this is know as QoS or message prefetching.
Prefetching is configured on a per-channel (typically) or per-connection
(rarely used) basis. To configure prefetching per channel, pass the
:prefetch option to the Channel constructor. Let us return to the example
we used in the “Message acknowledgements” section:
# app #1 will be given up to 3 messages at a time. If it does not
# send an ack after receiving the messages, then the messages will
# be routed to app #2.
channel1 = AMQP::Channel.new(connection1, :prefetch => 3)
# app #2 processes messages one-by-one and has to send an ack after receiving each message
channel2 = AMQP::Channel.new(connection2, :prefetch => 1)
In that example, one consumer prefetches three messages and another
consumer prefetches just one. If we take a look at the output that the
example produces, we will see that consumer1 fetched four messages
and acknowledged one. After that, all subsequent messages were delivered
to consumer2:
[consumer2] Received Message #0, redelivered = false, ack-ed
[consumer1] Got message #1, SKIPPED
[consumer1] Got message #2, SKIPPED
[consumer1] Got message #3, ack-ed
[consumer2] Received Message #4, redelivered = false, ack-ed
[consumer1] Got message #5, SKIPPED
—
by now consumer 1 has received three messages it did not acknowledge.
With :prefetch => 3, AMQP broker will not send it any more messages until
consumer 1 sends an ack
—
[consumer2] Received Message #6, redelivered = false, ack-ed
[consumer2] Received Message #7, redelivered = false, ack-ed
[consumer2] Received Message #8, redelivered = false, ack-ed
[consumer2] Received Message #9, redelivered = false, ack-ed
[consumer2] Received Message #10, redelivered = false, ack-ed
[consumer2] Received Message #11, redelivered = false, ack-ed
The prefetching setting is ignored for consumers that do not use explicit acknowledgements.
How message acknowledgements relate to transactions and Publisher Confirms
In cases where you cannot afford to lose a single message, AMQP 0.9.1 applications can use one or a combination of the following protocol features:
- Publisher confirms (a RabbitMQ-specific extension to AMQP 0.9.1)
- Publishing messages as immediate
- Transactions (noticeable overhead)
This topic is covered in depth in the Working With Exchanges guide. In this guide, we will only mention how message acknowledgements are related to AMQP transactions and the Publisher Confirms extension.
Let us consider a publisher application (P) that communications with a consumer (C) using AMQP 0.9.1. Their communication can be graphically represented like this:
----- ----- -----
| | S1 | | S2 | |
| P | ====> | B | ====> | C |
| | | | | |
----- ----- -----
We have two network segments, S1 and S2. Each of them may fail. P is concerned with making sure that messages cross S1, while broker (B) and C are concerned with ensuring that messages cross S2 and are only removed from the queue when they are processed successfully.
Message acknowledgements cover reliable delivery over S2 as well as successful processing. For S1, P has to use transactions (a heavyweight solution) or the more lightweight Publisher Confirms RabbitMQ extension.
Fetching messages when needed (“pull API”)
The AMQP 0.9.1 specification also provides a way for applications to
fetch (pull) messages from the queue only when necessary. For that, use
AMQP::Queue#pop:
queue.pop do |metadata, payload|
if payload
puts "Fetched a message: #{payload.inspect}, content_type: #{metadata.content_type}. Shutting down..."
else
puts "No messages in the queue"
end
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
exchange = channel.fanout("amq.fanout")
channel.queue("", :auto_delete => true, :exclusive => true) do |queue, declare_ok|
queue.bind(exchange)
puts "Bound. Publishing a message..."
exchange.publish("Ohai!")
EventMachine.add_timer(0.5) do
queue.pop do |metadata, payload|
if payload
puts "Fetched a message: #{payload.inspect}, content_type: #{metadata.content_type}. Shutting down..."
else
puts "No messages in the queue"
end
connection.close { EventMachine.stop }
end
end
end
end
If the queue is empty, then the payload argument will be nil,
otherwise arguments are identical to those of the
AMQP::Queue#subscribe callback.
Unsubscribing from messages
Sometimes it is necessary to unsubscribe from messages without deleting
a queue. To do that, use the AMQP::Queue#unsubscribe
method:
queue.unsubscribe
By default AMQP::Queue#unsubscribe uses the “:noack”
option to inform the broker that there is no need to send a
confirmation. In other words, it does not expect you to pass in a
callback, because the consumer tag on the instance and the registered
callback for messages are cleared immediately.
If an application needs to execute a piece of code after the broker
response arrives, AMQP::Queue#unsubscribe takes an optional callback:
queue.unsubscribe do |unbind_ok|
# server response arrived, handle it if necessary...
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
exchange = channel.fanout("amq.fanout")
channel.queue("", :auto_delete => true, :exclusive => true) do |queue, declare_ok|
queue.bind(exchange).subscribe do |headers, payload|
puts "Received a new message"
end
EventMachine.add_timer(0.3) do
queue.unsubscribe
puts "Unsubscribed. Shutting down..."
connection.close { EventMachine.stop }
end # EventMachine.add_timer
end # channel.queue
end
In AMQP parlance, unsubscribing from messages is often referred to as “cancelling a consumer”. Once a consumer is cancelled, messages will no longer be delivered to it, however, due to the asynchronous nature of the protocol, it is possible for “in flight” messages to be received after this call completes.
Fetching messages with AMQP::Queue#pop is still possible
even after a consumer is cancelled.
Unbinding queues from exchanges
To unbind a queue from an exchange use
AMQP::Queue#unbind:
queue.unbind(exchange)
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
channel.on_error do |ch, channel_close|
raise "Channel-level exception: #{channel_close.reply_text}"
end
exchange = channel.fanout("amq.fanout")
channel.queue("", :auto_delete => true, :exclusive => true) do |queue, declare_ok|
queue.bind(exchange)
EventMachine.add_timer(0.5) do
queue.unbind(exchange) do |_|
puts "Unbound. Shutting down..."
connection.close { EventMachine.stop }
end
end # EventMachine.add_timer
end # channel.queue
end
Note that trying to unbind a queue from an exchange that the queue was never bound to will result in a channel-level exception.
Querying the number of messages in a queue
It is possible to query the number of messages sitting in the queue by
declaring the queue with the :passive attribute set. The response
(queue.declare-ok AMQP method) will include the number of messages
along with other attributes. However, the amqp gem provides a
convenience method, AMQP::Queue#status:
queue.status do |number_of_messages, number_of_consumers|
puts
puts "# of messages in the queue #{queue.name} = #{number_of_messages}"
puts
end
Full example:
require 'rubygems'
require 'amqp'
puts "=> Queue#status example"
puts
AMQP.start(:host => 'localhost') do |connection|
channel = AMQP::Channel.new(connection)
queue_name = "amqpgem.integration.queue.status.queue"
exchange = channel.fanout("amqpgem.integration.queue.status.fanout", :auto_delete => true)
queue = channel.queue(queue_name, :auto_delete => true).bind(exchange)
100.times do |i|
print "."
exchange.publish(Time.now.to_i.to_s + "_#{i}", :key => queue_name)
end
$stdout.flush
EventMachine.add_timer(0.5) do
queue.status do |number_of_messages, number_of_consumers|
puts
puts "# of messages in the queue #{queue.name} = #{number_of_messages}"
puts
queue.purge
end
end
show_stopper = Proc.new do
$stdout.puts "Stopping..."
connection.close { EventMachine.stop }
end
Signal.trap "INT", show_stopper
EventMachine.add_timer(2, show_stopper)
end
Querying the number of consumers on a queue
It is possible to query the number of consumers on a queue by declaring
the queue with the :passive attribute set. The response
(queue.declare-ok AMQP method) will include the number of consumers
along with other attributes. However, the amqp gem provides a
convenience method, AMQP::Queue#status:
queue.status do |number_of_messages, number_of_consumers|
puts
puts "# of consumers on the queue #{queue.name} = #{number_of_consumers}"
puts
end
Full example:
require 'rubygems'
require 'amqp'
puts "=> Queue#status example"
puts
AMQP.start(:host => 'localhost') do |connection|
channel = AMQP::Channel.new(connection)
queue_name = "amqpgem.integration.queue.status.queue"
exchange = channel.fanout("amqpgem.integration.queue.status.fanout", :auto_delete => true)
queue = channel.queue(queue_name, :auto_delete => true).bind(exchange)
100.times do |i|
print "."
exchange.publish(Time.now.to_i.to_s + "_#{i}", :key => queue_name)
end
$stdout.flush
EventMachine.add_timer(0.5) do
queue.status do |number_of_messages, number_of_consumers|
puts
puts "# of consumer on the queue #{queue.name} = #{number_of_consumers}"
puts
queue.purge
end
end
show_stopper = Proc.new do
$stdout.puts "Stopping..."
connection.close { EventMachine.stop }
end
Signal.trap "INT", show_stopper
EventMachine.add_timer(2, show_stopper)
end
Purging queues
It is possible to purge a queue (remove all of the messages from it)
using AMQP::Queue#purge:
queue.purge
This method takes an optional callback. However, remember that this
operation is performed asynchronously. To run a piece of code when the
AMQP broker confirms that a queue has been purged, use a callback that
AMQP::Queue#purge takes:
queue.purge do |_|
puts "Purged #{queue.name}"
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
AMQP.start("amqp://guest:guest@dev.rabbitmq.com:5672") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
channel.on_error do |ch, channel_close|
raise "Channel-level exception: #{channel_close.reply_text}"
end
exchange = channel.fanout("amq.fanout")
channel.queue("", :auto_delete => true, :exclusive => true) do |queue, declare_ok|
queue.purge do |_|
puts "Purged #{queue.name}"
end
EventMachine.add_timer(0.5) do
connection.close { EventMachine.stop }
end # EventMachine.add_timer
end # channel.queue
end
Note that this example purges a newly declared queue with a unique server-generated name. When a queue is declared, it is empty, so for server-named queues, there is no need to purge them before they are used.
Deleting queues
To delete a queue, use AMQP::Queue#delete. When a queue
is deleted, all of the messages in it are deleted as well.
queue.delete
This method takes an optional callback. However, remember that this
operation is performed asynchronously. To run a piece of code when the
AMQP broker confirms that a queue has been deleted, use a callback that
AMQP::Queue#delete takes:
queue.delete do |_|
puts "Deleted #{queue.name}"
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
channel.on_error do |ch, channel_close|
raise "Channel-level exception: #{channel_close.reply_text}"
end
exchange = channel.fanout("amq.fanout")
channel.queue("", :auto_delete => true, :exclusive => true) do |queue, declare_ok|
EventMachine.add_timer(0.5) do
queue.delete do
puts "Deleted #{queue.name}"
connection.close { EventMachine. stop }
end
end # EventMachine.add_timer
end # channel.queue
end
Objects as message consumers and unit testing consumers in isolation
Since Ruby is a genuine object-oriented language, it is important to demonstrate how the Ruby amqp gem can be integrated into rich object-oriented code. This part of the guide focuses on queues and the problems/solutions concerning consumer applications (applications that primarily receive and process messages, as opposed to producers that publish them).
An AMQP::Queue#subscribe callback does not have to be a
block. It can be any Ruby object that responds to the call method. A
common technique is to combine
Object#method and Method#to_proc
and use object methods as message handlers.
An example to demonstrate this technique:
class Consumer
#
# API
#
def initialize(channel, queue_name = AMQ::Protocol::EMPTY_STRING)
@queue_name = queue_name
@channel = channel
# Consumer#handle_channel_exception will handle channel
# exceptions. Keep in mind that you can only register one error handler,
# so the last one registered "wins".
@channel.on_error(&method(:handle_channel_exception))
end # initialize
def start
@queue = @channel.queue(@queue_name, :exclusive => true)
# #handle_message method will be handling messages routed to @queue
@queue.subscribe(&method(:handle_message))
end # start
#
# Implementation
#
def handle_message(metadata, payload)
puts "Received a message: #{payload}, content_type = #{metadata.content_type}"
end # handle_message(metadata, payload)
def handle_channel_exception(channel, channel_close)
puts "Oops... a channel-level exception: code = #{channel_close.reply_code}, message = #{channel_close.reply_text}"
end # handle_channel_exception(channel, channel_close)
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
class Consumer
#
# API
#
def initialize(channel, queue_name = AMQ::Protocol::EMPTY_STRING)
@queue_name = queue_name
@channel = channel
@channel.on_error(&method(:handle_channel_exception))
end # initialize
def start
@queue = @channel.queue(@queue_name, :exclusive => true)
@queue.subscribe(&method(:handle_message))
end # start
#
# Implementation
#
def handle_message(metadata, payload)
puts "Received a message: #{payload}, content_type = #{metadata.content_type}"
end # handle_message(metadata, payload)
def handle_channel_exception(channel, channel_close)
puts "Oops... a channel-level exception: code = #{channel_close.reply_code}, message = #{channel_close.reply_text}"
end # handle_channel_exception(channel, channel_close)
end
class Producer
#
# API
#
def initialize(channel, exchange)
@channel = channel
@exchange = exchange
end # initialize(channel, exchange)
def publish(message, options = {})
@exchange.publish(message, options)
end # publish(message, options = {})
end
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
worker = Consumer.new(channel, "amqpgem.objects.integration")
worker.start
producer = Producer.new(channel, channel.default_exchange)
puts "Publishing..."
producer.publish("Hello, world", :routing_key => "amqpgem.objects.integration")
# stop in 2 seconds
EventMachine.add_timer(2.0) { connection.close { EventMachine.stop } }
end
In this example, Consumer instances have to be
instantiated with an AMQP::Channel instance. If the
message handling was done by an aggregated object, it would completely
separate the handling logic and would be make it easy to unit test in
isolation:
class Consumer
#
# API
#
def handle_message(metadata, payload)
puts "Received a message: #{payload}, content_type = #{metadata.content_type}"
end # handle_message(metadata, payload)
end
class Worker
#
# API
#
def initialize(channel, queue_name = AMQ::Protocol::EMPTY_STRING, consumer = Consumer.new)
@queue_name = queue_name
@channel = channel
@channel.on_error(&method(:handle_channel_exception))
@consumer = consumer
end # initialize
def start
@queue = @channel.queue(@queue_name, :exclusive => true)
@queue.subscribe(&@consumer.method(:handle_message))
end # start
#
# Implementation
#
def handle_channel_exception(channel, channel_close)
puts "Oops... a channel-level exception: code = #{channel_close.reply_code}, message = #{channel_close.reply_text}"
end # handle_channel_exception(channel, channel_close)
end
Full example:
#!/usr/bin/env ruby
# encoding: utf-8
require "rubygems"
require "amqp"
class Consumer
#
# API
#
def handle_message(metadata, payload)
puts "Received a message: #{payload}, content_type = #{metadata.content_type}"
end # handle_message(metadata, payload)
end
class Worker
#
# API
#
def initialize(channel, queue_name = AMQ::Protocol::EMPTY_STRING, consumer = Consumer.new)
@queue_name = queue_name
@channel = channel
@channel.on_error(&method(:handle_channel_exception))
@consumer = consumer
end # initialize
def start
@queue = @channel.queue(@queue_name, :exclusive => true)
@queue.subscribe(&@consumer.method(:handle_message))
end # start
#
# Implementation
#
def handle_channel_exception(channel, channel_close)
puts "Oops... a channel-level exception: code = #{channel_close.reply_code}, message = #{channel_close.reply_text}"
end # handle_channel_exception(channel, channel_close)
end
class Producer
#
# API
#
def initialize(channel, exchange)
@channel = channel
@exchange = exchange
end # initialize(channel, exchange)
def publish(message, options = {})
@exchange.publish(message, options)
end # publish(message, options = {})
#
# Implementation
#
def handle_channel_exception(channel, channel_close)
puts "Oops... a channel-level exception: code = #{channel_close.reply_code}, message = #{channel_close.reply_text}"
end # handle_channel_exception(channel, channel_close)
end
AMQP.start("amqp://guest:guest@dev.rabbitmq.com") do |connection, open_ok|
channel = AMQP::Channel.new(connection)
worker = Worker.new(channel, "amqpgem.objects.integration")
worker.start
producer = Producer.new(channel, channel.default_exchange)
puts "Publishing..."
producer.publish("Hello, world", :routing_key => "amqpgem.objects.integration")
# stop in 2 seconds
EventMachine.add_timer(2.0) { connection.close { EventMachine.stop } }
end
Note that the Consumer class demonstrated above can be easily tested in isolation without spinning up any AMQP connections:
require "ostruct"
require "json"
# RSpec example
describe Consumer do
describe "when a new message arrives" do
subject { described_class.new }
let(:metadata) do
o = OpenStruct.new
o.content_type = "application/json"
o
end
let(:payload) { JSON.encode({ :command => "reload_config" }) }
it "does some useful work" do
# check preconditions here if necessary
subject.handle_message(metadata, payload)
# add your code expectations here
end
end
end
Queue durability vs message durability
See Durability guide
Error handling and recovery
See Error handling and recovery guide
Vendor-specific extensions related to queues
See Vendor-specific Extensions guide
What to read next
The documentation is organized as several documentation guides, covering all kinds of topics. Guides related to this one are:
RabbitMQ implements a number of extensions to AMQP 0.9.1 functionality that are covered in the Vendor-specific Extensions guide. At least one extension, per-queue messages time-to-live (TTL), is related to this guide and can be used with the amqp gem 0.8.0 and later.