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NAME
Myriad - microservice coördination
SYNOPSIS
use Myriad;
Myriad->new->run;DESCRIPTION
Myriad provides a framework for dealing with asynchronous, microservice-based code. It is intended for use in an environment such as Kubernetes to support horizontal scaling for larger systems.
Overall this framework encourages - but does not enforce - single-responsibility in each microservice: each service should integrate with at most one external system, and integration should be kept in separate services from business logic or aggregation. This is at odds with common microservice frameworks, so perhaps it would be more accurate to say that this framework is aimed at developing "nanoservices" instead.
Do you need this?
If you expect to be dealing with more traffic than a single server can handle, or you have a development team larger than 30-50 or so, this might be of interest.
For a smaller system with a handful of users, it's probably overkill!
Modules and code layout
Myriad::Service - load this in your own code to turn it into a microservice
Myriad::RPC - the RPC abstraction layer, in
$self->rpcMyriad::Storage - abstraction layer for storage, available as
$self->storagewithin servicesMyriad::Subscription - the subscription handling layer, in
$self->subscription
Each of the three abstractions has various implementations. You'd set one on startup and that would provide functionality through the top-level abstraction layer. Service code generally shouldn't need to care which implementation is applied. There may however be cases where transactional behaviour differs between implementations, so there is some basic functionality planned for checking whether RPC/storage/subscription use the same underlying mechanism for transactional safety.
Storage
The Myriad::Storage abstract API is a good starting point here.
For storage implementations, we have:
Additional transport mechanisms may be available, see CPAN for details.
RPC
Simple request/response patterns are handled with the Myriad::RPC layer ("remote procedure call").
Details on the request are in Myriad::RPC::Request and the response to be sent back is in Myriad::RPC::Response.
Additional transport mechanisms may be available, see CPAN for details.
Subscriptions
The Myriad::Subscription abstraction layer defines the available API here.
Subscription implementations include:
Additional transport mechanisms may be available, see CPAN for details.
Transports
Note that some layers don't have implementations for all transports - MQ for example does not really provide a concept of "storage".
Each of these implementations is supposed to separate out the logic from the actual transport calls, so there's a separate ::Transport set of classes here:
which deal with the lower-level interaction with the protocol, connection management and so on. More details on that can be found in Myriad::Transport - but it's typically only useful for people working on the Myriad implementation itself.
Other classes
Documentation for these classes may also be of use:
Myriad::Exception - generic errors, provides "throw" in Myriad::Exception and we recommend that all service errors implement this rôle
Myriad::Plugin - adds specific functionality to services
Myriad::Bootstrap - startup used in
myriad.plfor providing autorestart and other functionalityMyriad::Service - base class for a service
Myriad::Registry - support for registering services and methods within the current process
Myriad::Config - general config support, commandline/file/storage
METHODS
loop
Returns the main IO::Async::Loop instance for this process.
services
Hashref of services that have been added to this instance, as name => Myriad::Service pairs.
configure_from_argv
Applies configuration from commandline parameters.
Expects a list of parameters and applies the following logic for each one:
if it contains
::and a wildcard*, it's treated as a service module base name, and all modules under that immediate namespace will be loadedif it contains
::, it's treated as a comma-separated list of service module names to loada
-prefix is a standard getopt parameter
redis
The Net::Async::Redis (or compatible) instance used for service coördination.
memory_transport
The Myriad::Transport::Memory instance.
rpc
The Myriad::RPC instance to serve RPC requests.
rpc_client
The Myriad::RPC::Client instance to request other services RPC.
http
The Net::Async::HTTP::Server (or compatible) instance used for health checks and metrics.
subscription
The Myriad::Subscription instance to manage events.
storage
The Myriad::Storage instance to manage data.
registry
Returns the common Myriad::Registry representing the current service state.
add_service
Instantiates and adds a new service to the "loop".
Returns the service instance.
service_by_name
Looks up the given service, returning the instance if it exists.
Will throw an exception if the service cannot be found.
ryu
a source to corresponde to any high level events.
shutdown
Requests shutdown.
on_start
Registers a coderef to be called during startup. The coderef is expected to return a Future.
on_shutdown
Registers a coderef to be called during shutdown.
The coderef is expected to return a Future indicating completion.
run_future
Returns a copy of the run Future.
This would resolve once the process is running and it's ready to accept requests.
shutdown_future
Returns a copy of the shutdown Future.
This would resolve once the process is about to shut down, triggered by a fault or a Unix signal.
setup_logging
Prepare for logging.
setup_tracing
Prepare OpenTracing collection.
setup_metrics
Prepare Metrics::Any::Adapter to collect metrics.
run
Starts the main loop.
Applies signal handlers for TERM and QUIT, then starts the loop.
SEE ALSO
Microservices are hardly a new concept, and there's a lot of prior art out there.
Key features that we attempt to provide:
reliable handling - requests and actions should be reliable by default
atomic storage - being able to record something in storage as part of the same transaction as acknowledging a message
flexible backends - support for various storage, RPC and subscription implementations, allowing for mix+match
zero transport option - for testing and smaller deployments, you might want to run everything in a single process
language-agnostic - implementations should be possible in languages other than Perl
first-class Kubernetes support - k8s is not required, but when available we should play to its strengths
minimal boilerplate - with an emphasis on rapid prototyping
These points tend to be incompatible with typical HTTP-based microservices frameworks, although this is offered as one of the transport mechanisms (with some limitations).
Perl
Here are a list of the Perl microservice implementations that we're aware of:
https://github.com/jmico/beekeeper - MQ-based (via STOMP), using AnyEvent
https://mojolicious.org - more of a web framework, but a popular one
Async::Microservice - AnyEvent-based, using HTTP as a protocol, currently a minimal wrapper intended to be used with OpenAPI services
Java
Although this is the textbook "enterprise-scale platform", Java naturally fits a microservice theme.
Spring Boot - One of the frameworks that integrates well with the traditional Java ecosystem, depends on HTTP as a transport. Although there is no unified storage layer, database access is available through connectors.
Micronaut - This framework has many integrations with industry-standard solutions - SQL, MongoDB, Kafka, Redis, gRPC - and they have integration guides for cloud-native solutions such as AWS or GCP.
DropWizard - A minimal framework that provides a RESTful interface and storage layer using Hibernate.
Helidon - Oracle's open source attempt, provides support for two types of transport and SQL access layer using standard Java's packages, built with cloud-native deployment in mind.
Python
Most of Python's frameworks provide tools to facilitate building logic blocks behind APIs (Flask, Django ..etc).
For work distribution, Celery is commonly used as a task queue abstraction.
Rust
https://rocket.rs/ - although this is a web framework, rather than a complete microservice system, it's reasonably popular for the request/response part of the equation
https://actix.rs/ - another web framework, this time with a focus on the actor pattern
JS
JS has many frameworks that help to implement the microservice architecture, some are:
Moleculer - generally a full-featured, well-designed microservices framework, highly recommended
PHP
Swoft - async support via Swoole's coroutines, HTTP/websockets based with additional support for Redis/database connection pooling and ORM
Cloud providers
Microservice support at the provider level:
AWS Lambda - trigger small containers based on logic, typically combined with other AWS services for data storage, message sending and other actions
"Google App Engine" - Google's own attempt
Heroku - Allow developers to build a microservices architecture based on the services they provide like the example they mentioned in this blog
AUTHOR
Deriv Group Services Ltd. DERIV@cpan.org
INHERITED METHODS
CONTRIBUTORS
Tom Molesworth
TEAM@cpan.orgPaul Evans
PEVANS@cpan.orgEyad Arnabeh
Nael Alolwani
LICENSE
Copyright Deriv Group Services Ltd 2020-2021. Licensed under the same terms as Perl itself.