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This is a basic layout for Go application projects. Note that it's basic in terms of content because it's focusing only on the general layout and not what you have inside. It's also basic because it's very high level and it doesn't go into great details in terms of how you can structure your project even further. For example, it doesn't try to cover the project structure you'd have with something like Clean Architecture.
This is NOT an official standard defined by the core Go dev team
. This is a set of common historical and emerging project layout patterns in the Go ecosystem. Some of these patterns are more popular than others. It also has a number of small enhancements along with several supporting directories common to any large enough real world application. Note that the core Go team provides a great set of general guidelines about structuring Go projects and what it means for your project when it's imported and when it's installed. See the Organizing a Go module
page in the official Go docs for more details. It includes the internal
and cmd
directory patterns (described below) and other useful information.
If you are trying to learn Go or if you are building a PoC or a simple project for yourself this project layout is an overkill. Start with something really simple instead (a single
main.gofile and
go.mod is more than enough).
As your project grows keep in mind that it'll be important to make sure your code is well structured otherwise you'll end up with a messy code with lots of hidden dependencies and global state. When you have more people working on the project you'll need even more structure. That's when it's important to introduce a common way to manage packages/libraries. When you have an open source project or when you know other projects import the code from your project repository that's when it's important to have private (aka internal
) packages and code. Clone the repository, keep what you need and delete everything else! Just because it's there it doesn't mean you have to use it all. None of these patterns are used in every single project. Even the vendor
pattern is not universal.
With Go 1.14 Go Modules
are finally ready for production. Use Go Modules
unless you have a specific reason not to use them and if you do then you don’t need to worry about $GOPATH and where you put your project. The basic go.mod
file in the repo assumes your project is hosted on GitHub, but it's not a requirement. The module path can be anything though the first module path component should have a dot in its name (the current version of Go doesn't enforce it anymore, but if you are using slightly older versions don't be surprised if your builds fail without it). See Issues 37554
and 32819
if you want to know more about it.
This project layout is intentionally generic and it doesn't try to impose a specific Go package structure.
This is a community effort. Open an issue if you see a new pattern or if you think one of the existing patterns needs to be updated.
If you need help with naming, formatting and style start by running gofmt
and staticcheck
. The previous standard linter, golint, is now deprecated and not maintained; use of a maintained linter such as staticcheck is recommended. Also make sure to read these Go code style guidelines and recommendations:
- https://talks.golang.org/2014/names.slide
- https://golang.org/doc/effective_go.html#names
- https://blog.golang.org/package-names
- https://github.com/golang/go/wiki/CodeReviewComments
- Style guideline for Go packages (rakyll/JBD)
See Go Project Layout
for additional background information.
More about naming and organizing packages as well as other code structure recommendations:
- GopherCon EU 2018: Peter Bourgon - Best Practices for Industrial Programming
- GopherCon Russia 2018: Ashley McNamara + Brian Ketelsen - Go best practices.
- GopherCon 2017: Edward Muller - Go Anti-Patterns
- GopherCon 2018: Kat Zien - How Do You Structure Your Go Apps
A Chinese post about Package-Oriented-Design guidelines and Architecture layer
Main applications for this project.
The directory name for each application should match the name of the executable you want to have (e.g., /cmd/myapp
).
Don't put a lot of code in the application directory. If you think the code can be imported and used in other projects, then it should live in the /pkg
directory. If the code is not reusable or if you don't want others to reuse it, put that code in the /internal
directory. You'll be surprised what others will do, so be explicit about your intentions!
It's common to have a small main
function that imports and invokes the code from the /internal
and /pkg
directories and nothing else.
See the /cmd
directory for examples.
Private application and library code. This is the code you don't want others importing in their applications or libraries. Note that this layout pattern is enforced by the Go compiler itself. See the Go 1.4 release notes
for more details. Note that you are not limited to the top level internal
directory. You can have more than one internal
directory at any level of your project tree.
You can optionally add a bit of extra structure to your internal packages to separate your shared and non-shared internal code. It's not required (especially for smaller projects), but it's nice to have visual clues showing the intended package use. Your actual application code can go in the /internal/app
directory (e.g., /internal/app/myapp
) and the code shared by those apps in the /internal/pkg
directory (e.g., /internal/pkg/myprivlib
).
Library code that's ok to use by external applications (e.g., /pkg/mypubliclib
). Other projects will import these libraries expecting them to work, so think twice before you put something here :-) Note that the internal
directory is a better way to ensure your private packages are not importable because it's enforced by Go. The /pkg
directory is still a good way to explicitly communicate that the code in that directory is safe for use by others. The I'll take pkg over internal
blog post by Travis Jeffery provides a good overview of the pkg
and internal
directories and when it might make sense to use them.
It's also a way to group Go code in one place when your root directory contains lots of non-Go components and directories making it easier to run various Go tools (as mentioned in these talks: Best Practices for Industrial Programming
from GopherCon EU 2018, GopherCon 2018: Kat Zien - How Do You Structure Your Go Apps and GoLab 2018 - Massimiliano Pippi - Project layout patterns in Go).
See the /pkg
directory if you want to see which popular Go repos use this project layout pattern. This is a common layout pattern, but it's not universally accepted and some in the Go community don't recommend it.
It's ok not to use it if your app project is really small and where an extra level of nesting doesn't add much value (unless you really want to :-)). Think about it when it's getting big enough and your root directory gets pretty busy (especially if you have a lot of non-Go app components).
The pkg
directory origins: The old Go source code used to use pkg
for its packages and then various Go projects in the community started copying the pattern (see this
Brad Fitzpatrick's tweet for more context).
Application dependencies (managed manually or by your favorite dependency management tool like the new built-in Go Modules
feature). The go mod vendor
command will create the /vendor
directory for you. Note that you might need to add the -mod=vendor
flag to your go build
command if you are not using Go 1.14 where it's on by default.
Don't commit your application dependencies if you are building a library.
Note that since 1.13
Go also enabled the module proxy feature (using https://proxy.golang.org
as their module proxy server by default). Read more about it here
to see if it fits all of your requirements and constraints. If it does, then you won't need the vendor
directory at all.
OpenAPI/Swagger specs, JSON schema files, protocol definition files.
See the /api
directory for examples.
Web application specific components: static web assets, server side templates and SPAs.
Configuration file templates or default configs.
Put your confd
or consul-template
template files here.
System init (systemd, upstart, sysv) and process manager/supervisor (runit, supervisord) configs.
Scripts to perform various build, install, analysis, etc operations.
These scripts keep the root level Makefile small and simple (e.g., https://github.com/hashicorp/terraform/blob/main/Makefile
).
See the /scripts
directory for examples.
Packaging and Continuous Integration.
Put your cloud (AMI), container (Docker), OS (deb, rpm, pkg) package configurations and scripts in the /build/package
directory.
Put your CI (travis, circle, drone) configurations and scripts in the /build/ci
directory. Note that some of the CI tools (e.g., Travis CI) are very picky about the location of their config files. Try putting the config files in the /build/ci
directory linking them to the location where the CI tools expect them (when possible).
IaaS, PaaS, system and container orchestration deployment configurations and templates (docker-compose, kubernetes/helm, terraform). Note that in some repos (especially apps deployed with kubernetes) this directory is called /deploy
.
Additional external test apps and test data. Feel free to structure the /test
directory anyway you want. For bigger projects it makes sense to have a data subdirectory. For example, you can have /test/data
or /test/testdata
if you need Go to ignore what's in that directory. Note that Go will also ignore directories or files that begin with "." or "_", so you have more flexibility in terms of how you name your test data directory.
See the /test
directory for examples.
Design and user documents (in addition to your godoc generated documentation).
See the /docs
directory for examples.
Supporting tools for this project. Note that these tools can import code from the /pkg
and /internal
directories.
See the /tools
directory for examples.
Examples for your applications and/or public libraries.
See the /examples
directory for examples.
External helper tools, forked code and other 3rd party utilities (e.g., Swagger UI).
Git hooks.
Other assets to go along with your repository (images, logos, etc).
This is the place to put your project's website data if you are not using GitHub pages.
See the /website
directory for examples.
Some Go projects do have a src
folder, but it usually happens when the devs came from the Java world where it's a common pattern. If you can help yourself try not to adopt this Java pattern. You really don't want your Go code or Go projects to look like Java :-)
Don't confuse the project level /src
directory with the /src
directory Go uses for its workspaces as described in How to Write Go Code
. The $GOPATH
environment variable points to your (current) workspace (by default it points to $HOME/go
on non-windows systems). This workspace includes the top level /pkg
, /bin
and /src
directories. Your actual project ends up being a sub-directory under /src
, so if you have the /src
directory in your project the project path will look like this: /some/path/to/workspace/src/your_project/src/your_code.go
. Note that with Go 1.11 it's possible to have your project outside of your GOPATH
, but it still doesn't mean it's a good idea to use this layout pattern.
-
Go Report Card - It will scan your code with
gofmt
,go vet
,gocyclo
,golint
,ineffassign
,license
andmisspell
. Replacegithub.aaakk.us.kg/golang-standards/project-layout
with your project reference. -
GoDoc - It will provide online version of your GoDoc generated documentation. Change the link to point to your project. -
Pkg.go.dev - Pkg.go.dev is a new destination for Go discovery & docs. You can create a badge using the badge generation tool.
-
Release - It will show the latest release number for your project. Change the github link to point to your project.
A more opinionated project template with sample/reusable configs, scripts and code is a WIP.