The Go programming language, often referred to as "golang", has gained a lot of well-deserved traction in the DevOps community. Many of the most popular tools such as Docker, Kubernetes, and Terraform are written in Go, but it can also be a great choice for building web applications and APIs.
Go provides you with all the speed and performance of a compiled language, but feels like coding in an interpreted language. This comes down to the great tooling that you get out of the box with a compiler, runner, test suite and code formatter provided by default. Add to that the robust and easily comprehensible approach to concurrency, to take maximum advantage of today's multi-core or multi-cpu execution environments, and it's clear why the Go community has grown so rapidly.
Go feels like it was created with specific goals in mind, leading to a deceptively simple language design that's straightforward to learn, without compromising on capabilities.
In this post, I'm going to show you how easy it is to develop a simple web application in Go, package it as a lightweight Docker image, and deploy it to Heroku. I'll also show a fairly new feature of Go: built-in package management.
Go Modules
I'm going to use Go's built-in module support for this article.
Go 1.0 was released in March 2012. Up until version 1.11 (released in August 2018), developing Go applications involved managing a GOPATH for each "workspace", analogous to java's JAVA_HOME
, and all of your Go source code and any third-party libraries were stored below the GOPATH
.
I always found this a bit off-putting, compared to developing code in languages like Ruby or Javascript where I could have a simpler directory structure isolating each project. In both of those languages, a single file (Gemfile
for Ruby, package.json
for Javascript) lists all the external libraries, and the package manager keeps track of managing and installing dependencies for me.
I'm not saying you can't manage the
GOPATH
environment variable to isolate projects from one another. I particularly find the package manager approach is easier.
Thankfully, Go now has excellent package management built in, so this is no longer a problem. However, you might find GOPATH
mentioned in many older blog posts and articles, which can be a little confusing.
Hello, World!
Let's get started on our web application. As usual, this is going to be a very simple "Hello, World!" app, because I want to focus on the development and deployment process, and keep this article to a reasonable length.
Pre-requisites
You'll need:
- A recent version of golang (I'm using 1.14.9.)
- Docker
- A Heroku account (The free account works fine for this example.)
- The Heroku command-line client
- git
Go mod init
To create our new project, we need to create a directory for it, and use the go mod init
command to initialize it as a Go module.
mkdir helloworld
cd helloworld
go mod init digitalronin/helloworld
It's common practice to use your github username to keep your project names globally unique, and avoid name conflicts with any of your project dependencies, but you can use any name you like.
You'll see a go.mod
file in the directory now. This is where Go will track any project dependencies. If you look at the contents of the file, they should look something like this:
module digitalronin/helloworld
go 1.14
Let's start committing our changes:
git init git add * git commit -m "Initial commit"
gin
We're going to use gin for our web application. Gin is a lightweight web framework, similar to Sinatra for Ruby, express.js for Javascript, or Flask for Python.
Create a file called hello.go
containing this code:
package main
import "github.com/gin-gonic/gin"
func main() {
r := gin.Default()
r.GET("/hello", func(c *gin.Context) {
c.String(200, "Hello, World!")
})
r.Run(":3000")
}
Let's break this down a little:
r := gin.Default()
This creates a router object, r
, using the built-in defaults that come with gin.
Then, we assign a handler function to be called for any HTTP GET requests to the path /hello
, and to return the string "Hello, World!" and a 200 (HTTP OK) status code:
r.GET("/hello", func(c *gin.Context) {
c.String(200, "Hello, World!")
})
Finally, we start our webserver and tell it to listen on port 3000:
r.Run(":3000")
To run this code, execute:
go run hello.go
You should see output like this:
go: finding module for package github.com/gin-gonic/gin
go: found github.com/gin-gonic/gin in github.com/gin-gonic/gin v1.6.3
[GIN-debug] [WARNING] Creating an Engine instance with the Logger and Recovery middleware already attached.
[GIN-debug] [WARNING] Running in "debug" mode. Switch to "release" mode in production.
- using env: export GIN_MODE=release
- using code: gin.SetMode(gin.ReleaseMode)
[GIN-debug] GET /hello --> main.main.func1 (3 handlers)
[GIN-debug] Listening and serving HTTP on :3000
Now if you visit http://localhost:3000/hello
in your web browser, you should see the message "Hello, World!"
Notice that we didn't have to install gin separately, or even edit our go.mod
file to declare it as a dependency. Go figures that out and makes the necessary changes for us, which is what's happening when we see these lines in the output:
go: finding module for package github.com/gin-gonic/gin
go: found github.com/gin-gonic/gin in github.com/gin-gonic/gin v1.6.3
If you look at the go.mod
file, you'll see it now contains this:
module digitalronin/helloworld
go 1.14
require github.com/gin-gonic/gin v1.6.3 // indirect
You will also see a go.sum
file now. This is a text file containing references to the specific versions of all the package dependencies, and their dependencies, along with a cryptographic hash of the contents of that version of the relevant module.
The go.sum
file serves a similar function to package-lock.json
for a Javascript project, or Gemfile.lock
in a Ruby project, and you should always check it into version control along with your source code.
Let's do that now:
git add *
git commit -m "Add 'Hello world' web server"
Serving HTML and JSON
I'm not going very far into what you can build with gin, but I do want to demonstrate a little more of its functionality. In particular, sending JSON responses and serving static files.
Let's look at JSON responses first. Add the following code to your hello.go
file, right after the r.GET
block:
api := r.Group("/api")
api.GET("/ping", func(c *gin.Context) {
c.JSON(200, gin.H{
"message": "pong",
})
})
Here we're creating a "group" of routes behind the path /api
with a single path /ping
which will return a JSON response.
With this code in place, run the server with go run
and then hit the new API endpoint:
curl http://localhost:3000/api/ping
You should get the response:
{"message":"pong"}
Finally, let's make our webserver serve static files. Gin has an additional library for this.
Change the import block at the top of the hello.go
file to this:
import (
"github.com/gin-gonic/contrib/static"
"github.com/gin-gonic/gin"
)
The most popular code editors have golang support packages you can install which will take care of the
import
declarations for you automatically, updating them for you whenever you use a new module in your code.
Then, add this line inside the main
function:
r.Use(static.Serve("/", static.LocalFile("./views", true)))
The full code for our web application now looks like this:
hello.go
package main
import (
"github.com/gin-gonic/contrib/static"
"github.com/gin-gonic/gin"
)
func main() {
r := gin.Default()
r.GET("/hello", func(c *gin.Context) {
c.String(200, "Hello, World!")
})
api := r.Group("/api")
api.GET("/ping", func(c *gin.Context) {
c.JSON(200, gin.H{
"message": "pong",
})
})
r.Use(static.Serve("/", static.LocalFile("./views", true)))
r.Run()
}
The r.Use(static.Serve...
line enables our webserver to serve any static files from the views
directory, so let's add a few:
mkdir -p views/css
views/css/stylesheet.css
body {
font-family: Arial;
}
h1 {
color: red;
}
views/index.html
<html>
<head>
<link rel="stylesheet" href="/css/stylesheet.css" />
</head>
<body>
<h1>Hello, World!</h1>
</body>
</html>
Now restart the webserver using go run hello.go
and visit http://localhost:3000
and you should see the styled message:
Dockerize
We've written our go web application, now let's package it up as a Docker image. We could create it as a Heroku buildpack, but one of the nice features of Go is that you can distribute your software as a single binary file. This is an area where Go really shines, and using a Docker-based Heroku deployment lets us take advantage of that. Also, this technique isn't limited to Go applications: You can use Docker-based deployment to Heroku for projects in any language. So, it's a good technique to understand.
So far, we've been running our code with the go run
command. To compile it into a single, executable binary, we simply run:
go build
This will compile all our Go source code and create a single file. By default, the output file will be named according to the module name, so in our case it will be called helloworld
.
We can run this:
./helloworld
And we can hit the same HTTP endpoints as before, either with curl
or our web browser.
The static files are not compiled into the binary, so if you put the
helloworld
file in a different directory, it will not find theviews
directory to serve our HTML and CSS content.>
That's all we need to do to create a binary for whatever platform we're developing on (in my case, my Mac laptop). However, to run inside a Docker container (for eventual deployment to Heroku) we need to compile a binary for whatever architecture our Docker container will run on.
I'm going to use alpine linux, so let's build our binary on that OS. Create a Dockerfile
with the following content:
FROM golang:1.14.9-alpine
RUN mkdir /build
ADD go.mod go.sum hello.go /build/
WORKDIR /build
RUN go build
In this image, we start with the golang
base image, add our source code, and run go build
to create our helloworld
binary.
We can build our Docker image like this:
docker build -t helloworld .
Don't forget the trailing
.
at the end of that command. It tells Docker we want to use the current directory as the build context.
This creates a Docker image with our helloworld
binary in it, but it also contains all the Go tools needed to compile our code, and we don't want any of that in our final image for deployment, because it makes the image unnecessarily large. It can also be a security risk to install unnecessary executables on your Docker images.
We can see the size of our Docker image like this:
$ docker images helloworld
REPOSITORY TAG IMAGE ID CREATED SIZE
helloworld latest 9657ec1ca905 4 minutes ago 370MB
For comparison, the alpine
image (a lightweight linux distribution, often used as a base for docker images) is much smaller:
$ docker images alpine
REPOSITORY TAG IMAGE ID CREATED SIZE
alpine latest caf27325b298 20 months ago 5.53MB
On my Mac, the helloworld
binary is around 14MB, so the golang image is much bigger than it needs to be.
What we want to do is use this Dockerfile to build our helloworld binary to run on alpine linux, then copy the compiled binary into an alpine base image, without all the extra golang tools.
We can do this using a "multistage" Docker build. Change the Dockerfile to look like this:
FROM golang:1.14.9-alpine AS builder
RUN mkdir /build
ADD go.mod go.sum hello.go /build/
WORKDIR /build
RUN go build
FROM alpine
RUN adduser -S -D -H -h /app appuser
USER appuser
COPY --from=builder /build/helloworld /app/
COPY views/ /app/views
WORKDIR /app
CMD ["./helloworld"]
On the first line, we label our initial Docker image AS builder
.
Later, we switch to a different base image FROM alpine
and then copy the helloworld
binary from our builder image like this:
COPY --from=builder /build/helloworld /app/
Build the new Docker image:
docker build -t helloworld .
Now, it's the size you would expect for a base alpine image plus our helloworld binary:
$ docker images helloworld
REPOSITORY TAG IMAGE ID CREATED SIZE
helloworld latest 1d6d9cb64c7e 8 seconds ago 20.7MB
We can run our webserver from the Docker image like this. (If you have another version running using go run hello.go
or ./helloworld
, you'll need to stop that one first, to free up port 3000.)
docker run --rm -p 3000:3000 helloworld
The dockerized webserver should behave just like the
go run hello.go
and./helloworld
versions except that it has its own copies of the static files. So, if you change any of the files inviews/
you won't see the changes until you rebuild the Docker image and restart the container.
Deploy to Heroku
Now that we have our dockerized web application, let's deploy it to Heroku. Heroku is a PaaS provider that makes it simple to deploy and host an application. You can set up and deploy your application through the Heroku UI, or through the Heroku CLI. For this example, we'll use the Heroku command-line application.
Getting PORT from an environment variable
We've hard-coded our webserver to run on port 3000, but that won't work on Heroku. Instead, we need to alter it to run on whichever port number is specified in the PORT
environment variable, which Heroku will supply automatically.
To do this, alter the r.Run
line near the bottom of our hello.go
file, and remove the ":3000"
string value so the line becomes:
r.Run()
The default behavior of gin is to run on whatever port is in the PORT
environment variable (or port 8080 if nothing is specified). This is exactly the behavior Heroku needs.
Setting up our Heroku app
First, log into Heroku:
heroku login
Now, create an app:
heroku create
Tell Heroku we want to build this project using a Dockerfile, rather than a buildpack:
heroku stack:set container
To do this, we also need to create a heroku.yml
file like this:
build:
docker:
web: Dockerfile
run:
web: ./helloworld
The heroku.yml
file is a manifest that defines our app and allows us to specify add-ons and config vars to use during app provisioning.
Next, add git and commit these files, then push to heroku to deploy:
git push heroku main
My git configuration uses
main
as the default branch. If your default branch is calledmaster
, then rungit push heroku master
instead.
You should see Heroku building the image from your Dockerfile, and pushing it to the Heroku Docker registry. Once the command completes, you can view the deployed application in your browser by running:
heroku open
Conclusion
To recap, here's a summary of what we covered today:
- Creating a golang web application, using go modules and the gin web framework to serve strings, JSON, and static files
- Using a multistage Dockerfile to create a lightweight Docker image
- Deploying a Docker-based application to Heroku using
heroku stack:set container
and aheroku.yml
file
I've only scratched the surface in this article on how to use Go to build web applications and APIs. I hope this gives you enough to get started on your own golang web applications.
Top comments (1)
Amazing. I followed all the steps and finally deployed my hellobossy app.