# Go Micro [](https://opensource.org/licenses/Apache-2.0) [](https://godoc.org/github.com/micro/go-micro) [](https://travis-ci.org/micro/go-micro) [](https://goreportcard.com/report/github.com/micro/go-micro)
Go Micro is a pluggable RPC framework for **microservices**. It provides the fundamental building blocks for writing distributed systems. It is part of [Micro](https://github.com/micro/micro), the microservice toolkit.
The **Micro** philosophy is sane defaults with a pluggable architecture. We provide defaults to get you started quickly but everything can be easily swapped out. It comes with built in support for {json,proto}-rpc encoding, consul or multicast dns for service discovery, http for communication and random hashed client side load balancing.
Everything in go-micro is **pluggable**. You can find and contribute to plugins at [github.com/micro/go-plugins](https://github.com/micro/go-plugins).
## The Features
Go Micro abstracts way the details of distributed systems and makes building microservices simple. Beneath the covers it provides a number of features.
**Service Discovery** - Applications are automatically registered with service discovery so they can locate each other.
**Load Balancing** - Smart client side load balancing is used to balance requests between instances of a service.
**Synchronous Communication** - Request-response is provided as a bidirectional streaming transport layer.
**Asynchronous Communication** - Microservices should promote an event driven architecture. Publish and Subscribe semantics are built in.
**Message Encoding** - Micro services can encode requests in a number of encoding formats and seamlessly decode based on the Content-Type header.
**RPC Client/Server** - The client and server leverage the above features and provide a clean simple interface for building microservices.
## Learn By Example
An example service can be found in [**examples/service**](https://github.com/micro/go-micro/tree/master/examples/service). The [**examples**](https://github.com/micro/go-micro/tree/master/examples) directory contains many more examples for using things such as middleware/wrappers, selector filters, pub/sub and code generation.
For the complete greeter example look at [**micro/examples/greeter**](https://github.com/micro/micro/tree/master/examples/greeter). Other examples can be found throughout the GitHub repository.
Check out the blog post to learn how to write go-micro services [https://blog.micro.mu/2016/03/28/go-micro.html](https://blog.micro.mu/2016/03/28/go-micro.html) or watch the talk from the [Golang UK Conf 2016](https://www.youtube.com/watch?v=xspaDovwk34).
## Join The Community
There's a growing community on Slack with hundreds of members and a mailing list for those that prefer the classic method of communication.
Join us to discuss, learn and contribute:
- [Mailing List](https://groups.google.com/forum/#!forum/microhq)
- [Slack](https://micro-services.slack.com) : [Invite](http://slack.micro.mu/)
## Getting Started
This is a quick getting started guide with the greeter service example.
### Prerequisites: Service Discovery
There's just one prerequisite. We need a service discovery system to resolve service names to their address.
The default discovery mechanism used in go-micro is Consul. Discovery is however pluggable so you can used
etcd, kubernetes, zookeeper, etc. Plugins can be found in [micro/go-plugins](https://github.com/micro/go-plugins).
### Zero Dependency Discovery
We can use multicast DNS with the built in MDNS registry for a zero dependency configuration.
Just pass `--registry=mdns` to any command
```
$ go run main.go --registry=mdns
```
### Consul Discovery
Alternatively we can use the default discovery system which is Consul.
**Install on OS X**
```
brew install consul
```
[Further installation instructions](https://www.consul.io/intro/getting-started/install.html)
**Run Consul**
```
$ consul agent -dev -advertise=127.0.0.1
```
### Run Service
```
$ go run examples/service/main.go
2016/03/14 10:59:14 Listening on [::]:50137
2016/03/14 10:59:14 Broker Listening on [::]:50138
2016/03/14 10:59:14 Registering node: greeter-ca62b017-e9d3-11e5-9bbb-68a86d0d36b6
```
### Test Service
```
$ go run examples/service/main.go --run_client
Hello John
```
## Writing a service
### Create request/response proto
One of the key requirements of microservices is strongly defined interfaces so we utilised protobuf to define the handler and request/response.
Here's a definition for the Greeter handler with the method Hello which takes a HelloRequest and HelloResponse both with one string arguments.
`go-micro/examples/service/proto/greeter.proto`:
```proto
syntax = "proto3";
service Greeter {
rpc Hello(HelloRequest) returns (HelloResponse) {}
}
message HelloRequest {
string name = 1;
}
message HelloResponse {
string greeting = 2;
}
```
### Install protobuf for code generation
We use a protobuf plugin for code generation. This is completely optional. Look at [examples/server](https://github.com/micro/go-micro/blob/master/examples/server/main.go)
and [examples/client](https://github.com/micro/go-micro/blob/master/examples/client/main.go) for examples without code generation.
```shell
go get github.com/micro/protobuf/{proto,protoc-gen-go}
```
There's still a need for proto compiler to generate Go stub code from our proto file. You can either use the micro fork above or the official repo `github.com/golang/protobuf`.
### Compile the protobuf file
```shell
protoc -I$GOPATH/src --go_out=plugins=micro:$GOPATH/src \
$GOPATH/src/github.com/micro/go-micro/examples/service/proto/greeter.proto
```
### Define the service
Below is the code sample for the Greeter service. It basically implements the interface defined above for the Greeter handler,
initialises the service, registers the handler and then runs itself. Simple as that.
`go-micro/examples/service/main.go`:
```go
package main
import (
"fmt"
micro "github.com/micro/go-micro"
proto "github.com/micro/go-micro/examples/service/proto"
"golang.org/x/net/context"
)
type Greeter struct{}
func (g *Greeter) Hello(ctx context.Context, req *proto.HelloRequest, rsp *proto.HelloResponse) error {
rsp.Greeting = "Hello " + req.Name
return nil
}
func main() {
// Create a new service. Optionally include some options here.
service := micro.NewService(
micro.Name("greeter"),
micro.Version("latest"),
micro.Metadata(map[string]string{
"type": "helloworld",
}),
)
// Init will parse the command line flags. Any flags set will
// override the above settings. Options defined here will
// override anything set on the command line.
service.Init()
// Register handler
proto.RegisterGreeterHandler(service.Server(), new(Greeter))
// Run the server
if err := service.Run(); err != nil {
fmt.Println(err)
}
}
```
### Run service
```
go run examples/service/main.go
2016/03/14 10:59:14 Listening on [::]:50137
2016/03/14 10:59:14 Broker Listening on [::]:50138
2016/03/14 10:59:14 Registering node: greeter-ca62b017-e9d3-11e5-9bbb-68a86d0d36b6
```
### Define a client
Below is the client code to query the greeter service. Notice we're using the code generated client interface `proto.NewGreeterClient`.
This reduces the amount of boiler plate code we need to write. The greeter client can be reused throughout the code if need be.
`client.go`
```go
package main
import (
"fmt"
micro "github.com/micro/go-micro"
proto "github.com/micro/go-micro/examples/service/proto"
"golang.org/x/net/context"
)
func main() {
// Create a new service. Optionally include some options here.
service := micro.NewService(micro.Name("greeter.client"))
// Create new greeter client
greeter := proto.NewGreeterClient("greeter", service.Client())
// Call the greeter
rsp, err := greeter.Hello(context.TODO(), &proto.HelloRequest{Name: "John"})
if err != nil {
fmt.Println(err)
}
// Print response
fmt.Println(rsp.Greeting)
}
```
### Run the client
```shell
go run client.go
Hello John
```
## How does it work?
Go Micro is a framework that addresses the fundamental requirements to write microservices.
Let's dig into the core components.
### Registry
The registry provides a service discovery mechanism to resolve names to addresses. It can be backed by consul, etcd, zookeeper, dns, gossip, etc.
Services should register using the registry on startup and deregister on shutdown. Services can optionally provide an expiry TTL and reregister
on an interval to ensure liveness and that the service is cleaned up if it dies.
### Selector
The selector is a load balancing abstraction which builds on the registry. It allows services to be "filtered" using filter functions and "selected"
using a choice of algorithms such as random, roundrobin, leastconn, etc. The selector is leveraged by the Client when making requests. The client
will use the selector rather than the registry as it provides that built in mechanism of load balancing.
### Transport
The transport is the interface for synchronous request/response communication between services. It's akin to the golang net package but provides
a higher level abstraction which allows us to switch out communication mechanisms e.g http, rabbitmq, websockets, NATS. The transport also
supports bidirectional streaming. This is powerful for client side push to the server.
### Broker
The broker provides an interface to a message broker for asynchronous pub/sub communication. This is one of the fundamental requirements of an event
driven architecture and microservices. By default we use an inbox style point to point HTTP system to minimise the number of dependencies required
to get started. However there are many message broker implementations available in go-plugins e.g RabbitMQ, NATS, NSQ, Google Cloud Pub Sub.
### Codec
The codec is used for encoding and decoding messages before transporting them across the wire. This could be json, protobuf, bson, msgpack, etc.
Where this differs from most other codecs is that we actually support the RPC format here as well. So we have JSON-RPC, PROTO-RPC, BSON-RPC, etc.
It separates encoding from the client/server and provides a powerful method for integrating other systems such as gRPC, Vanadium, etc.
### Server
The server is the building block for writing a service. Here you can name your service, register request handlers, add middeware, etc. The service
builds on the above packages to provide a unified interface for serving requests. The built in server is an RPC system. In the future there maybe
other implementations. The server also allows you to define multiple codecs to serve different encoded messages.
### Client
The client provides an interface to make requests to services. Again like the server, it builds on the other packages to provide a unified interface
for finding services by name using the registry, load balancing using the selector, making synchronous requests with the transport and asynchronous
messaging using the broker.
The above components are combined at the top-level of micro as a **Service**.
## Community Plugins
By default go-micro only provides a few implementation of each interface at the core but it's completely pluggable. There's already dozens of plugins which are available at [github.com/micro/go-plugins](https://github.com/micro/go-plugins). Contributions are welcome!
## Sponsors
## Next steps
- [Examples Directory](https://github.com/micro/go-micro/tree/master/examples)
- [Example Services](https://github.com/micro/go-micro#example-services)
- [Micro Toolkit](https://github.com/micro/micro)
- Join the [Slack](https://micro-services.slack.com)! - [Invite Here](http://slack.micro.mu/)
## Contributing
- Checkout the issues list [github.com/micro/go-micro/issues](https://github.com/micro/go-micro/issues)
- Join the Slack to discuss the roadmap
- PR plugins to [github.com/micro/go-plugins](https://github.com/micro/go-plugins)
- Write example services for others to use