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Alchemy Micro-Service Framework: Using RabbitMQ Instead of HTTP

Alchemy Micro-services Framework

Alchemy Micro-Service Framework: Using RabbitMQ Instead of HTTP

Alchemy Micro-Service Framework: Using RabbitMQ Instead of HTTP Alchemy Micro-Service Framework: Using RabbitMQ Instead of HTTP

Alchemyis a framework for creating highly available systems that are built from micro-services . Alchemy includes service discovery, easy deployment, smart load balancing, and is also designed to be polyglot, so you can use the best languages to solve all your problems; Alchemy already has implementations inNode.js andRuby.

This repository is a description of how Alchemy works, how it is implemented, and how to create services. Also included are a few examples of how to write services and to use Alchemy with:

  1. Docker and docker-compose which can be used with Travis CI (results are here )
  2. Vagrant with CoreOS for local testing
  3. An Amazon Web Services Cloud Formation template using an Elastic Load Balancer, Auto Scaling Groups and CoreOS for production and other cloud environments

How Alchemy Services Work

Alchemy uses the RabbitMQ message broker to pass requests between services. Each Alchemy service registers two queues with RabbitMQ:

  1. a service queue is the name of the service and is shared amongst all instances of a service
  2. a response queue is the name of a service instance so is unique

A service communicates by putting a request (that includes its own response queue ) on a target’s service queue . Then an instance of the target service will consume, process, then respond to the request on the received response queue .

** For the purpose of clarity I will note a service with letters e.g. A , B and service instances with numbers, e.g. A1 is service A instance 1 . **

For example, service A1 wants to message service B :

 |----------|                                                  |------------| | RabbitMQ | <-- 1. Send request on queue B   --------------- | Service A1 | |          |                                                  |            | |          | --- 2. Consume request from B  -> |------------| |            | |          |                                   | Service B1 | |            | |          | <-- 3. Respond on queue A1     -- |------------| |            | |          |                                                  |            | |----------| --- 4. Receive response on A1  ----------------> |------------| 

Service A sends a request to the service queue B . This message is consumed by a service instance B1 , processed, and the result published on the response queue of the service instance A1 where it can be received.

This design makes the Alchemy framework:

  • High Availability : because RabbitMQ can run as a cluster across multiple machines where queues can be highly available , and multiple instances of Alchemy services can be run simultaneously; **No single machine is a point of failure in the Alchemy Framework.
  • Smart Load Balancing : If several instances of the service B were running with different available resources, each instance would regulate its own load by only consuming messages it can process. Compared to round-robin load balancing where instances with the least resources would be under heavy load while instances with the most resources are idle.
  • Service Discovery : service A1 does not know that it is communicating with service instance B1 so cannot know where it is deployed. It only knows that the service B is who it is calling. This abstraction means that B1 could be on a different computer, a different data center, or in a different hemisphere.
  • Easy Deployment : starting and stopping an instance of a service can be done without notifying any other part of the system. So no Consul or other service registry is needed. Additionally, if a new version of a service became available, it can be deployed alongside the old version to have a zero downtime upgrade.
  • Error Recovery : If B1 dies while processing a message RabbitMQ will put the message back on the queue which can then be processed by another instance. Service A1 will not know this has happened and will probably just see the message take longer than usual. This also means that messages may be processed more than once, so implementing idempotent micro-services is recommended.
  • Polyglot Architecture : Service A1 could be implemented in Ruby while B1 is implemented in Node.js. They both just have to follow the same standard as described in this documentation. Even service instances can be implemented in different languages (if you wanted to compare performance).

Resources and Routing

An individual service will likely implement many related resources , e.g. an authentication service could implement session , user , and credential resources. In alchemy it is possible for service to communicate directly with a resource without even knowing which service implements it. This disconnects the implementation of a resource from a service, so Alchemy services only need to know what they want and not where to find it.

In Alchemy each resource is represented by a path , e.g. /v1/users . The service binds its service queue to the resources.exchange RabbitMQ Topic Exchange with a binding key created from the path, e.g. v1.users.# . For a service to call a resource it posts a message to the resources.exchange with a routing key created from the path it wants to call, e.g. /v1/users/1337 is converted to v1.users.1337 , where RabbitMQ will route the message to the correct service queue.

For example, service A1 wants to send a message with path /v1/users/1337 :

 |----------|                                                  |------------| | RabbitMQ | <-- 1. Send request to /v1/users/1337 ---------- | Service A1 | | resource |                                                  |            | | exchange | --- 2. Consume request from B  -> |------------| |            | |          |                                   | Service B1 | |            | |          | <-- 3. Respond on queue A1     -- |------------| |            | |          |                                                  |            | |----------| --- 4. Receive response on A1  ----------------> |------------| 

Service B1 implements the resource with path /v1/users , when it starts it binds its service queue B to the exchange resources.exchange with the binding key v1.users.# . When a message with a path /v1/users/1337 is sent, the path is converted into the routing key v1.users.1337 and sent on the resources.exchange which routes the message to the service queue B for B1 to process and respond.

This method of resource routing will route all sub-paths to a bound resource path. This means that it is important to ensure there are no routing conflicts exist between resources.

The Alchemy API

The specific API for each Alchemy implementation may be slightly different because of the implementation language, but they follow similar designs and function signatures.

Service Construction

A service is initialized with initialize(name, options = {}, service_fn) where the name will be the name of the service queue and used to generate a response queue by adding a random string after the name. The keys for options are:

  1. ampq_uri : the URL location of RabbitMQ e.g. "amqp://localhost"
  2. prefetch : the number of messages to prefect and process in parallel
  3. timeout : the length of time in milliseconds that the service will wait for a response to a message
  4. resource_paths and array of paths as strings, e.g. ["/v1/posts","/v1/tags"]

The service_fn is the function that will process the received messages (that are defined below). It can return an object with keys:

  1. body : A string of body information
  2. headers : an object with headers in is, e.g. {"X-HEADER-KEY": "value"}
  3. status_code : an HTTP status code

For example:

{   "body": "{/"created_at/":/"2016-02-27T04:31:58.200Z/"}",   "http_status": "200",   "headers": {     "Content-Type": "application/json; charset=UTF-8"   } } 

When Processing a Message Goes Bad

Sometimes when processing a message an error occurs that requires the process to be tried again. The service_fn can not acknowledg (or NAck ) processing the message by throwing or returning a NAckError . This error will cause RabbitMQ to put the message back on the queue to be retried again by the original or another service.

This is very dangerous!If the cause of the NAckError happens repeatedly the message will be retried (potentially indefinitely) and cause your system to run out of resources. It is best used in cases where the cause of the error would quickly be resolved.

Life Cycle

The life cycle functions are:

  1. start to create the queues in RabbitMQ, bind the resources to the exchange, and start listening to the service queue for messages to process.
  2. stop will shutdown the service by first stopping processing new messages from the service queue, then waiting for the currently processing messages and requests to finish, then shutting down the RabbitMQ connection.

Communication

The format of an Alchemy request on a queue reuses concepts from the HTTP protocol like status codes, headers, to be more interoperable and easier to understand. A request sent across RabbitMQ is encoded as a JSON string with the keys:

Request Information:

  1. body : A string of the body, e.g ‘hello’
  2. verb : The HTTP verb for the request, e.g. GET
  3. headers : an object with headers in is, e.g. {"X-HEADER-KEY": "value"}
  4. path : the path of the request, e.g. "/v1/users/1337"
  5. query : an object with keys for query, e.g. {'q': 'alchemy'}

Call information:

  1. scheme : the scheme used for the call,, e.g. http
  2. host : the host called to make the call, e.g. localhost
  3. port : the port the call was made on, e.g. 8080

Authentication information:

  1. session : this is an object of undefined structure that can be passed in the message so that a service does not need to re-authenticate with each message (this can be quite expensive in a call hitting many services).

For example a call to create a user will be:

{   "body": "{/"name/":/"alice/",/"password/":/"1234/"}",   "verb": "POST",   "headers": {     "Content-Type": "application/json; charset=UTF-8"   },   "path": "/users",   "query": {},   "scheme": "https",   "host": "localhost",   "port": 8080,   "session": {'user_id': "2", 'session_id': "4321"} } 

Sending requests to another service can either be done directly to a service by providing a the name of the service queue, or to a resource via the resource exchange that will use the path contained within the request to create the routing key.

Additionally, Alchemy allows a service to send a request , which requires a response, and to send a message , which does not require a response.

These options create the four functions:

  1. send_message_to_service(service_name, message) : send a message to a service and not require a response
  2. send_message_to_resource(message) : send a message to a resource and not require a response
  3. send_request_to_service(service_name, message) : send a request to a service and require a response
  4. send_request_to_resource(message) : send a request to a resource and require a response

When Sending a Request or Message Goes Bad

When a message is sent to either a service that does not exist or to a resource path that is not bound to a service, the function will return or throw a MessageNotDeliveredError . This is essentially a 404 no found error as the message never reached a service to be processed, but it allows a service to deal with that in its own way (like a fail whale).

When a request is sent it will not wait forever for a response. If the request takes longer than the option timeout a TimeoutError is thrown or returned. This is essentially a 408 request timeout error which can be handled by the service. A timeout could happen if there is a service queue, but no service listening on the queue.

AMQ Message Options

The AMQ/RabbitMQ message options that are being used by Alchemy to send requests are:

  1. message_id : a unique identifier for the request
  2. type : http
  3. content_encoding : '8bit'
  4. content_type : 'application/json' , this is the type of the request on RabbitMQ not the type of the actual message sent by the service.
  5. expiration : the options timeout value
  6. reply_to : the name of the response queue that the response message should be put on. If no reply_to is set, then no response is sent (this is how messages are sent)
  7. mandatory : true this will make messages be returned if they do not find a queue

The options for the response are:

  1. message_id : a unique identifier for the response
  2. type : http_response
  3. correlation_id : The message_id of the request to be responded to

Router

An important part of Alchemy is the gateway between a client calling over HTTP and the services which are listening on RabbitMQ. TheAlchemy Router is this gateway that converts incoming HTTP requests into Alchemy requests sent on over RabbitMQ.

The Router can be used either:

  1. as an application installed using npm via npm install -g alchemy-router then run with alchemy-router
  2. as an npm package that can be extended and customised by writingexpress middelware.
  3. as a Docker container quay.io/loyalty_nz/alchemy-router

How the Router works is:

  1. An HTTP request is sent from a client to Alchemy
  2. The HTTP request is received by the Router and converted into an Alchemy request
  3. The request is sent to the correct Alchemy service or resource
  4. The response is unpacked and returned to the HTTP client

In a typical Alchemy deployment there would be many instances of the Router running being load balanced across by an application like Elastic Load Balancer or HAProxy . This can add performance and availability benefits.

Example Sinatra API Micro-Service Application

The Ruby implementation of Alchemy, Alchemy Flux , comes with aRack server implementation that handles the life-cycle and processing requests of an Alchemy service. The Alchemy Rack server supports popular frameworks like Rails and Sinatra to make it very easy to build new, or move old, services onto Alchemy.

For example, a simple Sinatra application in the Alchemy framework has the files:

# ./Gemfile source 'https://rubygems.org'  gem 'sinatra' gem 'alchemy-flux' 
# ./config.ru ENV['ALCHEMY_SERVICE_NAME'] = 'helloworld.service' ENV['ALCHEMY_RESOURCE_PATHS'] = '/v1/hello'  require 'alchemy-flux' require './service' run Sinatra::Application 
# ./service.rb require 'sinatra'  get '/v1/hello' do   content_type :json   {'hello' => 'world!'}.to_json end 

To run this service we use rackup and specify alchemy as the Rack server:

bundle install bundle exec rackup -s alchemy 

The service will now be listening on RabbitMQ for incoming messages, running a router (as described above) and calling the router with /v1/hello over HTTP this will route the message to the Sinatra micro-service.

Alchemy Implementations (So Far)

Alchemy Framework Implementations:

  1. Ruby has Alchemy-Flux which is the reference implementation
  2. Node.js has Alchemy Ether

Projects that use Alchemy

  1. Hoodoo A micro-services CRUD and RESTful framework
  2. Alchemy Resource a Hoodoo interoperable ramework for Node.js
  3. Router a router/gateway from HTTP calls to Alchemy services

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