Terragrunt is a thin wrapper for Terraform that provides extra tools for keeping your Terraform configurations DRY, working with multiple Terraform modules, and managing remote state.
-
Install Terragrunt by going to the Releases Page, downloading the binary for your OS, renaming it to
terragrunt
, and adding it to your PATH.- See the Install Terragrunt docs for other installation options.
-
Go into a folder with your Terraform configurations (
.tf
files) and create aterraform.tfvars
file with aterragrunt = { ... }
block that contains the configuration for Terragrunt (check out the Use cases section for the types of configuration Terragrunt supports):terragrunt = { # (put your Terragrunt configuration here) }
-
Now, instead of running
terraform
directly, run all the standard Terraform commands usingterragrunt
:terragrunt get terragrunt plan terragrunt apply terragrunt output terragrunt destroy
Terragrunt forwards almost all commands, arguments, and options directly to Terraform, using whatever version of Terraform you already have installed. However, based on the settings in your
terraform.tfvars
file, Terragrunt can configure remote state, locking, extra arguments, and lots more. -
Terragrunt is a direct implementation of the ideas expressed in Terraform: Up & Running. Additional background reading that will help explain the motivation for Terragrunt includes the Gruntwork.io blog posts How to create reusable infrastructure with Terraform modules and How to use Terraform as a team.
-
Check out the terragrunt-infrastructure-modules-example and terragrunt-infrastructure-live-example repos for fully-working sample code that demonstrates how to use Terragrunt.
Note that third-party Terragrunt packages may not be updated with the latest version, but are often close. Please check your version against the latest available on the Releases Page.
You can install Terragrunt on OSX using Homebrew: brew install terragrunt
.
WARNING: the snap installer seems to have a bug where it does not allow Terragrunt to work with Terraform and Git dependencies, so we currently do not recommend using it. See the manual install instructions below, instead.
You can install Terragrunt on Linux systems using snap: snap install terragrunt
.
You can install Terragrunt manually by going to the Releases Page,
downloading the binary for your OS, renaming it to terragrunt
, and adding it to your PATH.
Terragrunt supports the following use cases:
- Keep your Terraform code DRY
- Keep your remote state configuration DRY
- Keep your CLI flags DRY
- Execute Terraform commands on multiple modules at once
- Work with multiple AWS accounts
- Motivation
- Remote Terraform configurations
- How to use remote configurations
- Achieve DRY Terraform code and immutable infrastructure
- Working locally
- Important gotcha: working with relative file paths
- Using Terragrunt with private Git repos
Consider the following file structure, which defines three environments (prod, qa, stage) with the same infrastructure in each one (an app, a MySQL database, and a VPC):
└── live
├── prod
│ ├── app
│ │ └── main.tf
│ ├── mysql
│ │ └── main.tf
│ └── vpc
│ └── main.tf
├── qa
│ ├── app
│ │ └── main.tf
│ ├── mysql
│ │ └── main.tf
│ └── vpc
│ └── main.tf
└── stage
├── app
│ └── main.tf
├── mysql
│ └── main.tf
└── vpc
└── main.tf
The contents of each environment will be more or less identical, except perhaps for a few settings (e.g. the prod environment may run bigger or more servers). As the size of the infrastructure grows, having to maintain all of this duplicated code between environments becomes more error prone. You can reduce the amount of copy paste using Terraform modules, but even the code to instantiate a module and set up input variables, output variables, providers, and remote state can still create a lot of maintenance overhead.
How can you keep your Terraform code DRY so that you only have to define it once, no matter how many environments you have?
Terragrunt has the ability to download remote Terraform configurations. The idea is that you define the Terraform code
for your infrastructure just once, in a single repo, called, for example, modules
:
└── modules
├── app
│ └── main.tf
├── mysql
│ └── main.tf
└── vpc
└── main.tf
This repo contains typical Terraform code, with one difference: anything in your code that should be different between
environments should be exposed as an input variable. For example, the app
module might expose the following
variables:
variable "instance_count" {
description = "How many servers to run"
}
variable "instance_type" {
description = "What kind of servers to run (e.g. t2.large)"
}
These variables allow you to run smaller/fewer servers in qa and stage to save money and larger/more servers in prod to ensure availability and scalability.
In a separate repo, called, for example, live
, you define the code for all of your environments, which now consists
of just one .tfvars
file per component (e.g. app/terraform.tfvars
, mysql/terraform.tfvars
, etc). This gives you
the following file layout:
└── live
├── prod
│ ├── app
│ │ └── terraform.tfvars
│ ├── mysql
│ │ └── terraform.tfvars
│ └── vpc
│ └── terraform.tfvars
├── qa
│ ├── app
│ │ └── terraform.tfvars
│ ├── mysql
│ │ └── terraform.tfvars
│ └── vpc
│ └── terraform.tfvars
└── stage
├── app
│ └── terraform.tfvars
├── mysql
│ └── terraform.tfvars
└── vpc
└── terraform.tfvars
Notice how there are no Terraform configurations (.tf
files) in any of the folders. Instead, each .tfvars
file
specifies a terraform { ... }
block that specifies from where to download the Terraform code, as well as the
environment-specific values for the input variables in that Terraform code. For example,
stage/app/terraform.tfvars
may look like this:
terragrunt = {
terraform {
source = "git::[email protected]:foo/modules.git//app?ref=v0.0.3"
}
}
instance_count = 3
instance_type = "t2.micro"
(Note: the double slash (//
) is intentional and required. It's part of Terraform's Git syntax for module
sources. Terraform may display a "Terraform initialized in an empty
directory" warning, but you can safely ignore it.)
And prod/app/terraform.tfvars
may look like this:
terragrunt = {
terraform {
source = "git::[email protected]:foo/modules.git//app?ref=v0.0.1"
}
}
instance_count = 10
instance_type = "m2.large"
Notice how the two terraform.tfvars
files set the source
URL to the same app
module, but at different
versions (i.e. stage
is testing out a newer version of the module). They also set the parameters for the
app
module to different values that are appropriate for the environment: smaller/fewer servers in stage
to save money, larger/more instances in prod
for scalability and high availability.
Check out the terragrunt-infrastructure-modules-example and terragrunt-infrastructure-live-example repos for fully-working sample code that demonstrates this new folder structure.
Once you've set up your live
and modules
repositories, all you need to do is run terragrunt
commands in the
live
repository. For example, to deploy the app
module in qa, you would do the following:
cd live/qa/app
terragrunt apply
When Terragrunt finds the terraform
block with a source
parameter in live/qa/app/terraform.tfvars
file, it will:
-
Download the configurations specified via the
source
parameter into a temporary folder. This downloading is done by using the terraform init command, so thesource
parameter supports the exact same syntax as the module source parameter, including local file paths, Git URLs, and Git URLs withref
parameters (useful for checking out a specific tag, commit, or branch of Git repo). Terragrunt will download all the code in the repo (i.e. the part before the double-slash//
) so that relative paths work correctly between modules in that repo. -
Copy all files from the current working directory into the temporary folder. This way, Terraform will automatically read in the variables defined in the
terraform.tfvars
file. -
Execute whatever Terraform command you specified in that temporary folder.
With this new approach, copy/paste between environments is minimized. The .tfvars
files contain solely the variables
that are different between environments. To create a new environment, you copy an old one and update just the
environment-specific values in the .tfvars
files, which is about as close to the "essential complexity" of the
problem as you can get.
Just as importantly, since the Terraform module code is now defined in a single repo, you can version it (e.g., using Git
tags and referencing them using the ref
parameter in the source
URL, as in the stage/app/terraform.tfvars
and
prod/app/terraform.tfvars
examples above), and promote a single, immutable version through each environment (e.g.,
qa -> stage -> prod). This idea is inspired by Kief Morris' blog post Using Pipelines to Manage Environments with
Infrastructure as Code.
If you're testing changes to a local copy of the modules
repo, you you can use the --terragrunt-source
command-line
option or the TERRAGRUNT_SOURCE
environment variable to override the source
parameter. This is useful to point
Terragrunt at a local checkout of your code so you can do rapid, iterative, make-a-change-and-rerun development:
cd live/stage/app
terragrunt apply --terragrunt-source ../../../modules//app
(Note: the double slash (//
) here too is intentional and required. Terragrunt downloads all the code in the folder
before the double-slash into the temporary folder so that relative paths between modules work correctly. Terraform may
display a "Terraform initialized in an empty directory" warning, but you can safely ignore it.)
The first time you set the source
parameter to a remote URL, Terragrunt will download the code from that URL into a tmp folder.
It will NOT download it again afterwords unless you change that URL. That's because downloading code—and more importantly,
reinitializing remote state, redownloading provider plugins, and redownloading modules—can take a long time. To avoid adding 10-90
seconds of overhead to every Terragrunt command, Terragrunt assumes all remote URLs are immutable, and only downloads them once.
Therefore, when working locally, you should use the --terragrunt-source
parameter and point it at a local file path as described
in the previous section. Terragrunt will copy the local files every time you run it, which is nearly instantaneous, and doesn't
require reinitializing everything, so you'll be able to iterate quickly.
If you need to force Terragrunt to redownload something from a remote URL, run Terragrunt with the --terragrunt-source-update
flag
and it'll delete the tmp folder, download the files from scratch, and reinitialize everything. This can take a while, so avoid it
and use --terragrunt-source
when you can!
One of the gotchas with downloading Terraform configurations is that when you run terragrunt apply
in folder foo
,
Terraform will actually execute in some temporary folder such as /tmp/foo
. That means you have to be especially
careful with relative file paths, as they will be relative to that temporary folder and not the folder where you ran
Terragrunt!
In particular:
-
Command line: When using file paths on the command line, such as passing an extra
-var-file
argument, you should use absolute paths:# Use absolute file paths on the CLI! terragrunt apply -var-file /foo/bar/extra.tfvars
-
Terragrunt configuration: When using file paths directly in your Terragrunt configuration (
terraform.tfvars
), such as in anextra_arguments
block, you can't use hard-coded absolute file paths, or it won't work on your teammates' computers. Therefore, you should utilize the Terragrunt built-in functionget_tfvars_dir()
to use a relative file path:terragrunt = { terraform { source = "git::[email protected]:foo/modules.git//frontend-app?ref=v0.0.3" extra_arguments "custom_vars" { commands = [ "apply", "plan", "import", "push", "refresh" ] # With the get_tfvars_dir() function, you can use relative paths! arguments = [ "-var-file=${get_tfvars_dir()}/../common.tfvars", "-var-file=terraform.tfvars" ] } } }
See the get_tfvars_dir() documentation for more details.
The easiest way to use Terragrunt with private Git repos is to use SSH authentication.
Configure your Git account so you can use it with SSH
(see the guide for GitHub here)
and use the SSH URL for your repo, prepended with git::ssh:https://
:
terragrunt = {
terraform {
source = "git::ssh:https://[email protected]/foo/modules.git//path/to/module?ref=v0.0.1"
}
}
Look up the Git repo for your repository to find the proper format.
Note: In automated pipelines, you may need to run the following command for your
Git repository prior to calling terragrunt
to ensure that the ssh host is registered
locally, e.g.:
$ ssh -T -oStrictHostKeyChecking=no [email protected] || true
- Motivation
- Filling in remote state settings with Terragrunt
- Create remote state and locking resources automatically
Terraform supports remote state storage via a variety of backends that you configure as follows:
terraform {
backend "s3" {
bucket = "my-terraform-state"
key = "frontend-app/terraform.tfstate"
region = "us-east-1"
encrypt = true
dynamodb_table = "my-lock-table"
}
}
Unfortunately, the backend
configuration does not support interpolation. This makes it hard to keep your code
DRY if you have multiple Terraform modules. For example,
consider the following folder structure, which uses different Terraform modules to deploy a backend app, frontend app,
MySQL database, and a VPC:
├── backend-app
│ └── main.tf
├── frontend-app
│ └── main.tf
├── mysql
│ └── main.tf
└── vpc
└── main.tf
To use remote state with each of these modules, you would have to copy/paste the exact same backend
configuration
into each of the main.tf
files. The only thing that would differ between the configurations would be the key
parameter: e.g., the key
for mysql/main.tf
might be mysql/terraform.tfstate
and the key
for
frontend-app/main.tf
might be frontend-app/terraform.tfstate
.
To keep your remote state configuration DRY, you can use Terragrunt. You still have to specify the backend
you want
to use in each module, but instead of copying and pasting the configuration settings over and over again into each
main.tf
file, you can leave them blank:
terraform {
# The configuration for this backend will be filled in by Terragrunt
backend "s3" {}
}
To fill in the settings via Terragrunt, create a terraform.tfvars
file in the root folder and in each of the
Terraform modules:
├── terraform.tfvars
├── backend-app
│ ├── main.tf
│ └── terraform.tfvars
├── frontend-app
│ ├── main.tf
│ └── terraform.tfvars
├── mysql
│ ├── main.tf
│ └── terraform.tfvars
└── vpc
├── main.tf
└── terraform.tfvars
In your root terraform.tfvars
file, you can define your entire remote state configuration just once in a
remote_state
block, as follows:
terragrunt = {
remote_state {
backend = "s3"
config {
bucket = "my-terraform-state"
key = "${path_relative_to_include()}/terraform.tfstate"
region = "us-east-1"
encrypt = true
dynamodb_table = "my-lock-table"
}
}
}
The remote_state
block supports all the same backend types
as Terraform. The next time you run terragrunt
, it will automatically configure all the settings in the
remote_state.config
block, if they aren't configured already, by calling terraform
init.
In each of the child terraform.tfvars
files, such as mysql/terraform.tfvars
, you can tell Terragrunt to
automatically include all the settings from the root terraform.tfvars
file as follows:
terragrunt = {
include {
path = "${find_in_parent_folders()}"
}
}
The include
block tells Terragrunt to use the exact same Terragrunt configuration from the terraform.tfvars
file
specified via the path
parameter. It behaves exactly as if you had copy/pasted the Terraform configuration from
the included file's terragrunt = { ... } configuration into mysql/terraform.tfvars
, but this approach is much easier to maintain! Including variables defined outside of the terragrunt block is discussed in #132.
The child .tfvars
file's terragrunt.terraform
settings will be merged into the parent file's terragrunt.terraform
settings as follows:
- If an
extra_arguments
block in the child has the same name as anextra_arguments
block in the parent, then the child's block will override the parent's.- Specifying an empty
extra_arguments
block in a child with the same name will effectively remove the parent's block.
- Specifying an empty
- If an
extra_arguments
block in the child has a different name thanextra_arguments
blocks in the parent, then both the parent and child'sextra_arguments
will be effective.- The child's
extra_arguments
will be placed after the parent'sextra_arguments
on the terraform command line. - Therefore, if a child's and parent's
extra_arguments
include.tfvars
files with the same variable defined, the value from the.tfvars
file from the child'sextra_arguments
will be used by terraform.
- The child's
- The
source
field in the child will overridesource
field in the parent
Other settings in the child .tfvars
file's terragrunt
block (e.g. remote_state
) override the respective
settings in the parent.
The terraform.tfvars
files above use two Terragrunt built-in functions:
-
find_in_parent_folders()
: This function returns the path to the firstterraform.tfvars
file it finds in the parent folders above the currentterraform.tfvars
file. In the example above, the call tofind_in_parent_folders()
inmysql/terraform.tfvars
will return../terraform.tfvars
. This way, you don't have to hard code thepath
parameter in every module. -
path_relative_to_include()
: This function returns the relative path between the currentterraform.tfvars
file and the path specified in itsinclude
block. We typically use this in a rootterraform.tfvars
file so that each Terraform child module stores its Terraform state at a differentkey
. For example, themysql
module will have itskey
parameter resolve tomysql/terraform.tfstate
and thefrontend-app
module will have itskey
parameter resolve tofrontend-app/terraform.tfstate
.
See the Interpolation Syntax docs for more info.
Check out the terragrunt-infrastructure-modules-example and terragrunt-infrastructure-live-example repos for fully-working sample code that demonstrates how to use Terragrunt to manage remote state.
When you run terragrunt
with remote_state
configuration, it will automatically create the following resources if
they don't already exist:
-
S3 bucket: If you are using the S3 backend for remote state storage and the
bucket
you specify inremote_state.config
doesn't already exist, Terragrunt will create it automatically, with versioning enabled. -
DynamoDB table: If you are using the S3 backend for remote state storage and you specify a
dynamodb_table
(a DynamoDB table used for locking) inremote_state.config
, if that table doesn't already exist, Terragrunt will create it automatically, including a primary key calledLockID
.
Note: If you specify a profile
key in remote_state.config
, Terragrunt will automatically use this AWS profile
when creating the S3 bucket or DynamoDB table.
- Motivation
- Multiple extra_arguments blocks
- extra_arguments for init
- Required and optional var-files
- Handling whitespace
Sometimes you may need to pass extra CLI arguments every time you run certain terraform
commands. For example, you
may want to set the lock-timeout
setting to 20 minutes for all commands that may modify remote state so that
Terraform will keep trying to acquire a lock for up to 20 minutes if someone else already has the lock rather than
immediately exiting with an error.
You can configure Terragrunt to pass specific CLI arguments for specific commands using an extra_arguments
block
in your terraform.tfvars
file:
terragrunt = {
terraform {
# Force Terraform to keep trying to acquire a lock for
# up to 20 minutes if someone else already has the lock
extra_arguments "retry_lock" {
commands = [
"init",
"apply",
"refresh",
"import",
"plan",
"taint",
"untaint"
]
arguments = [
"-lock-timeout=20m"
]
}
}
}
Each extra_arguments
block includes an arbitrary name (in the example above, retry_lock
), a list of commands
to
which the extra arguments should be add, a list of arguments
or required_var_files
or optional_var_files
to add.
With the configuration above, when you run terragrunt apply
, Terragrunt will call Terraform as follows:
When available, it is preferable to use interpolation functions such as get_terraform_commands_that_need_locking and get_terraform_commands_that_need_vars since they provide the complete list of terraform commands that make use of the desired parameter:
terragrunt = {
terraform {
# Force Terraform to keep trying to acquire a lock for up to 20 minutes if someone else already has the lock
extra_arguments "retry_lock" {
commands = ["${get_terraform_commands_that_need_locking()}"]
arguments = ["-lock-timeout=20m"]
}
}
}
> terragrunt apply
terraform apply -lock-timeout=20m
You can specify one or more extra_arguments
blocks. The arguments
in each block will be applied any time you call
terragrunt
with one of the commands in the commands
list. If more than one extra_arguments
block matches a
command, the arguments will be added in the order of of appearance in the configuration. For example, in addition to
lock settings, you may also want to pass custom -var-file
arguments to several commands:
terragrunt = {
terraform {
# Force Terraform to keep trying to acquire a lock for
# up to 20 minutes if someone else already has the lock
extra_arguments "retry_lock" {
commands = [
"init",
"apply",
"refresh",
"import",
"plan",
"taint",
"untaint"
]
arguments = [
"-lock-timeout=20m"
]
}
# Pass custom var files to Terraform
extra_arguments "custom_vars" {
commands = [
"apply",
"plan",
"import",
"push",
"refresh"
]
arguments = [
"-var", "foo=bar",
"-var", "region=us-west-1"
]
}
}
}
With the configuration above, when you run terragrunt apply
, Terragrunt will call Terraform as follows:
> terragrunt apply
terraform apply -lock-timeout=20m -var foo=bar -var region=us-west-1
Extra arguments for the init
command have some additional behavior and constraints.
In addition to being appended to the terraform init
command that is run when you explicitly run terragrunt init
,
extra_arguments
for init
will also be appended to the init
commands that are automatically
run during other commands (see Auto-Init).
You must not specify the -from-module
option (aka. the SOURCE
argument for terraform < 0.10.0) or the DIR
argument
in the extra_arguments
for init
. This option and argument will be provided automatically by terragrunt.
Here's an example of configuring extra_arguments
for init
in an environment in which terraform plugins are manually installed,
rather than relying on terraform to automatically download them.
terragrunt = {
terraform = {
...
extra_arguments "init_args" {
commands = [
"init"
]
arguments = [
"-get-plugins=false",
"-plugin-dir=/my/terraform/plugin/dir",
]
}
}
}
One common usage of extra_arguments is to include tfvars files. instead of using arguments, it is simpler to use either required_var_files
or optional_var_files
. Both options require only to provide the list of file to include. The only difference is that required_var_files
will add the extra argument -var-file=<your file>
for each file specified and if they don't exist, terraform will complain. Using
optional_var_files
instead, terragrunt will only add the -var-file=<your file>
for existing files. This allows many conditional
configurations based on environment variables as you can see in the following example:
/my/tf
├── terraform.tfvars
├── prod.tfvars
├── us-west-2.tfvars
├── backend-app
│ ├── main.tf
│ ├── dev.tfvars
│ └── terraform.tfvars
├── frontend-app
│ ├── main.tf
│ ├── us-east-1.tfvars
│ └── terraform.tfvars
terragrunt = {
terraform {
extra_arguments "conditional_vars" {
commands = [
"apply",
"plan",
"import",
"push",
"refresh"
]
required_var_files = [
"${get_parent_tfvars_dir()}/terraform.tfvars"
]
optional_var_files = [
"${get_parent_tfvars_dir()}/${get_env("TF_VAR_env", "dev")}.tfvars",
"${get_parent_tfvars_dir()}/${get_env("TF_VAR_region", "us-east-1")}.tfvars",
"${get_tfvars_dir()}/${get_env("TF_VAR_env", "dev")}.tfvars",
"${get_tfvars_dir()}/${get_env("TF_VAR_region", "us-east-1")}.tfvars"
]
}
}
See the get_tfvars_dir() and get_parent_tfvars_dir() documentation for more details.
Note that terragrunt cannot interpolate terraform variables (${var.xxx}) in the terragrunt configuration, your variables have to be defined through TF_VAR_xxx environment variable to be referred by terragrunt.
With the configuration above, when you run terragrunt apply-all
, Terragrunt will call Terraform as follows:
> terragrunt apply-all
[backend-app] terraform apply -var-file=/my/tf/terraform.tfvars -var-file=/my/tf/backend-app/dev.tfvars
[frontend-app] terraform apply -var-file=/my/tf/terraform.tfvars -var-file=/my/tf/frontend-app/us-east-1.tfvars
> TF_VAR_env=prod terragrunt apply-all
[backend-app] terraform apply -var-file=/my/tf/terraform.tfvars -var-file=/my/tf/prod.tfvars
[frontend-app] terraform apply -var-file=/my/tf/terraform.tfvars -var-file=/my/tf/prod.tfvars -var-file=/my/tf/frontend-app/us-east-1.tfvars
> TF_VAR_env=prod TF_VAR_region=us-west-2 terragrunt apply-all
[backend-app] terraform apply -var-file=/my/tf/terraform.tfvars -var-file=/my/tf/prod.tfvars -var-file=/my/tf/us-west-2.tfvars
[frontend-app] terraform apply -var-file=/my/tf/terraform.tfvars -var-file=/my/tf/prod.tfvars -var-file=/my/tf/us-west-2.tfvars
The list of arguments cannot include whitespaces, so if you need to pass command line arguments that include
spaces (e.g. -var bucket=example.bucket.name
), then each of the arguments will need to be a separate item in the
arguments
list:
terragrunt = {
terraform {
extra_arguments "bucket" {
arguments = [
"-var", "bucket=example.bucket.name",
]
commands = [
"apply",
"plan",
"import",
"push",
"refresh"
]
}
}
}
With the configuration above, when you run terragrunt apply
, Terragrunt will call Terraform as follows:
> terragrunt apply
terraform apply -var bucket=example.bucket.name
- Motivation
- The apply-all, destroy-all, output-all and plan-all commands
- Dependencies between modules
- Testing multiple modules locally
Let's say your infrastructure is defined across multiple Terraform modules:
root
├── backend-app
│ └── main.tf
├── frontend-app
│ └── main.tf
├── mysql
│ └── main.tf
├── redis
│ └── main.tf
└── vpc
└── main.tf
There is one module to deploy a frontend-app, another to deploy a backend-app, another for the MySQL database, and so
on. To deploy such an environment, you'd have to manually run terraform apply
in each of the subfolder, wait for it
to complete, and then run terraform apply
in the next subfolder. How do you avoid this tedious and time-consuming
process?
To be able to deploy multiple Terraform modules in a single command, add a terraform.tfvars
file to each module:
root
├── backend-app
│ ├── main.tf
│ └── terraform.tfvars
├── frontend-app
│ ├── main.tf
│ └── terraform.tfvars
├── mysql
│ ├── main.tf
│ └── terraform.tfvars
├── redis
│ ├── main.tf
│ └── terraform.tfvars
└── vpc
├── main.tf
└── terraform.tfvars
Inside each terraform.tfvars
file, add a terragrunt = { ... }
block to identify this as a module managed by
Terragrunt (the block can be empty or include any of the configs described in this documentation):
terragrunt = {
# Put your Terragrunt configuration here
}
Now you can go into the root
folder and deploy all the modules within it by using the apply-all
command:
cd root
terragrunt apply-all
When you run this command, Terragrunt will recursively look through all the subfolders of the current working
directory, find all terraform.tfvars
files with a terragrunt = { ... }
block, and run terragrunt apply
in each
one concurrently.
Similarly, to undeploy all the Terraform modules, you can use the destroy-all
command:
cd root
terragrunt destroy-all
To see the currently applied outputs of all of the subfolders, you can use the output-all
command:
cd root
terragrunt output-all
Finally, if you make some changes to your project, you could evaluate the impact by using plan-all
command:
Note: It is important to realize that you could get errors running plan-all
if you have dependencies between your projects
and some of those dependencies haven't been applied yet.
Ex: If module A depends on module B and module B hasn't been applied yet, then plan-all will show the plan for B, but exit with an error when trying to show the plan for A.
cd root
terragrunt plan-all
If your modules have dependencies between them—for example, you can't deploy the backend-app until MySQL and redis are deployed—you'll need to express those dependencies in your Terragrunt configuration as explained in the next section.
Consider the following file structure:
root
├── backend-app
│ ├── main.tf
│ └── terraform.tfvars
├── frontend-app
│ ├── main.tf
│ └── terraform.tfvars
├── mysql
│ ├── main.tf
│ └── terraform.tfvars
├── redis
│ ├── main.tf
│ └── terraform.tfvars
└── vpc
├── main.tf
└── terraform.tfvars
Let's assume you have the following dependencies between Terraform modules:
backend-app
depends onmysql
,redis
, andvpc
frontend-app
depends onbackend-app
andvpc
mysql
depends onvpc
redis
depends onvpc
vpc
has no dependencies
You can express these dependencies in your terraform.tfvars
config files using a dependencies
block. For example,
in backend-app/terraform.tfvars
you would specify:
terragrunt = {
dependencies {
paths = ["../vpc", "../mysql", "../redis"]
}
}
Similarly, in frontend-app/terraform.tfvars
, you would specify:
terragrunt = {
dependencies {
paths = ["../vpc", "../backend-app"]
}
}
Once you've specified the dependencies in each terraform.tfvars
file, when you run the terragrunt apply-all
or
terragrunt destroy-all
, Terragrunt will ensure that the dependencies are applied or destroyed, respectively, in the
correct order. For the example at the start of this section, the order for the apply-all
command would be:
- Deploy the VPC
- Deploy MySQL and Redis in parallel
- Deploy the backend-app
- Deploy the frontend-app
If any of the modules fail to deploy, then Terragrunt will not attempt to deploy the modules that depend on them. Once
you've fixed the error, it's usually safe to re-run the apply-all
or destroy-all
command again, since it'll be a
no-op for the modules that already deployed successfully, and should only affect the ones that had an error the last
time around.
To check all of your dependencies and validate the code in them, you can use the validate-all
command.
If you are using Terragrunt to configure remote Terraform configurations and all
of your modules have the source
parameter set to a Git URL, but you want to test with a local checkout of the code,
you can use the --terragrunt-source
parameter:
cd root
terragrunt plan-all --terragrunt-source /source/modules
If you set the --terragrunt-source
parameter, the xxx-all
commands will assume that parameter is pointing to a
folder on your local file system that has a local checkout of all of your Terraform modules. For each module that is
being processed via a xxx-all
command, Terragrunt will read in the source
parameter in that module's .tfvars
file, parse out the path (the portion after the double-slash), and append the path to the --terragrunt-source
parameter to create the final local path for that module.
For example, consider the following .tfvars
file:
terragrunt = {
terraform {
source = "git::[email protected]:acme/infrastructure-modules.git//networking/vpc?ref=v0.0.1"
}
}
If you run terragrunt apply-all --terragrunt-source: /source/infrastructure-modules
, then the local path Terragrunt
will compute for the module above will be /source/infrastructure-modules//networking/vpc
.
The most secure way to manage infrastructure in AWS is to use multiple AWS accounts. You define all your IAM users in one account (e.g., the "security" account) and deploy all of your infrastructure into a number of other accounts (e.g., the "dev", "stage", and "prod" accounts). To access those accounts, you login to the security account and assume an IAM role in the other accounts.
There are a few ways to assume IAM roles when using AWS CLI tools, such as Terraform:
-
One option is to create a named profile, each with a different role_arn parameter. You then tell Terraform which profile to use via the
AWS_PROFILE
environment variable. The downside to using profiles is that you have to store your AWS credentials in plaintext on your hard drive. -
Another option is to use environment variables and the AWS CLI. You first set the credentials for the security account (the one where your IAM users are defined) as the environment variables
AWS_ACCESS_KEY_ID
andAWS_SECRET_ACCESS_KEY
and runaws sts assume-role --role-arn <ROLE>
. This gives you back a blob of JSON that contains newAWS_ACCESS_KEY_ID
andAWS_SECRET_ACCESS_KEY
values you can set as environment variables to allow Terraform to use that role. The advantage of this approach is that you can store your AWS credentials in a secret store and never write them to disk in plaintext. The disadvantage is that assuming an IAM role requires several tedious steps. Worse yet, the credentials you get back from theassume-role
command are only good for up to 1 hour, so you have to repeat this process often. -
A final option is to modify your AWS provider with the assume_role configuration and your S3 backend with the role_arn parameter. You can then set the credentials for the security account (the one where your IAM users are defined) as the environment variables
AWS_ACCESS_KEY_ID
andAWS_SECRET_ACCESS_KEY
and when you runterraform apply
orterragrunt apply
, Terraform/Terragrunt will assume the IAM role you specify automatically. The advantage of this approach is that you can store your AWS credentials in a secret store and never write them to disk in plaintext, and you get fresh credentials on every run ofapply
, without the complexity of callingassume-role
. The disadvantage is that you have to modify all your Terraform / Terragrunt code to set therole_arn
param and your Terraform backend configuration will change (and prompt you to manually confirm the update!) every time you change the IAM role you're using.
To avoid these frustrating trade-offs, you can configure Terragrunt to assume an IAM role for you, as described next.
To tell Terragrunt to assume an IAM role, just set the --terragrunt-iam-role
command line argument:
terragrunt --terragrunt-iam-role "arn:aws:iam::ACCOUNT_ID:role/ROLE_NAME" apply
Alternatively, you can set the TERRAGRUNT_IAM_ROLE
environment variable:
export TERRAGRUNT_IAM_ROLE="arn:aws:iam::ACCOUNT_ID:role/ROLE_NAME"
terragrunt apply
Terragrunt will call the sts assume-role
API on your behalf and expose the credentials it gets back as environment
variables when running Terraform. The advantage of this approach is that you can store your AWS credentials in a secret
store and never write them to disk in plaintext, you get fresh credentials on every run of Terragrunt, without the
complexity of calling assume-role
yourself, and you don't have to modify your Terraform code or backend configuration
at all.
This section contains detailed documentation for the following aspects of Terragrunt:
- AWS credentials
- AWS IAM policies
- Interpolation Syntax
- Auto-Init
- CLI options
- Configuration
- Migrating from Terragrunt v0.11.x and Terraform 0.8.x and older
- Developing Terragrunt
- License
Terragrunt uses the official AWS SDK for Go, which means that it will automatically load credentials using the AWS standard approach. If you need help configuring your credentials, please refer to the Terraform docs.
Your AWS user must have an IAM policy which grants permissions for interacting with DynamoDB and S3. Terragrunt will automatically create the configured DynamoDB tables and S3 buckets for storing remote state if they do not already exist.
The following is an example IAM policy for use with Terragrunt. The policy grants the following permissions:
- all DynamoDB permissions in all regions for tables used by Terragrunt
- all S3 permissions for buckets used by Terragrunt
Before using this policy, make sure to replace 1234567890
with your AWS account id and terragrunt*
with
your organization's naming convention for AWS resources for Terraform remote state.
{
"Version": "2012-10-17",
"Statement": [
{
"Sid": "AllowAllDynamoDBActionsOnAllTerragruntTables",
"Effect": "Allow",
"Action": "dynamodb:*",
"Resource": [
"arn:aws:dynamodb:*:1234567890:table/terragrunt*"
]
},
{
"Sid": "AllowAllS3ActionsOnTerragruntBuckets",
"Effect": "Allow",
"Action": "s3:*",
"Resource": [
"arn:aws:s3:::terragrunt*",
"arn:aws:s3:::terragrunt*/*"
]
}
]
}
Terragrunt allows you to use Terraform interpolation syntax
(${...}
) to call specific Terragrunt built-in functions. Note that Terragrunt built-in functions only work within a
terragrunt = { ... }
block. Terraform does NOT process interpolations in .tfvars
files.
- find_in_parent_folders()
- path_relative_to_include()
- path_relative_from_include()
- get_env(NAME, DEFAULT)
- get_tfvars_dir()
- get_parent_tfvars_dir()
- get_terraform_commands_that_need_vars()
- get_terraform_commands_that_need_input()
- get_terraform_commands_that_need_locking()
- get_aws_account_id()
find_in_parent_folders()
searches up the directory tree from the current .tfvars
file and returns the relative path
to to the first terraform.tfvars
in a parent folder or exit with an error if no such file is found. This is
primarily useful in an include
block to automatically find the path to a parent .tfvars
file:
terragrunt = {
include {
path = "${find_in_parent_folders()}"
}
}
The function takes an optional name
parameter that allows you to specify a different filename to search for:
terragrunt = {
include {
path = "${find_in_parent_folders("some-other-file-name.tfvars")}"
}
}
You can also pass an optional second fallback
parameter which causes the function to return the fallback value
(instead of exiting with an error) if the file in the name
parameter cannot be found:
terragrunt = {
include {
path = "${find_in_parent_folders("some-other-file-name.tfvars", "fallback.tfvars")}"
}
}
path_relative_to_include()
returns the relative path between the current .tfvars
file and the path
specified in
its include
block. For example, consider the following folder structure:
├── terraform.tfvars
└── prod
└── mysql
└── terraform.tfvars
└── stage
└── mysql
└── terraform.tfvars
Imagine prod/mysql/terraform.tfvars
and stage/mysql/terraform.tfvars
include all settings from the root
terraform.tfvars
file:
terragrunt = {
include {
path = "${find_in_parent_folders()}"
}
}
The root terraform.tfvars
can use the path_relative_to_include()
in its remote_state
configuration to ensure
each child stores its remote state at a different key
:
terragrunt = {
remote_state {
backend = "s3"
config {
bucket = "my-terraform-bucket"
region = "us-east-1"
key = "${path_relative_to_include()}/terraform.tfstate"
}
}
}
The resulting key
will be prod/mysql/terraform.tfstate
for the prod mysql
module and
stage/mysql/terraform.tfstate
for the stage mysql
module.
path_relative_from_include()
returns the relative path between the path
specified in its include
block and the current
.tfvars
file (it is the counterpart of path_relative_to_include()
). For example, consider the following folder structure:
├── sources
| ├── mysql
| | └── *.tf
| └── secrets
| └── mysql
| └── *.tf
└── terragrunt
└── common.tfvars
├── mysql
| └── terraform.tfvars
├── secrets
| └── mysql
| └── terraform.tfvars
└── terraform.tfvars
Imagine terragrunt/mysql/terraform.tfvars
and terragrunt/secrets/mysql/terraform.tfvars
include all settings from the root
terraform.tfvars
file:
terragrunt = {
include {
path = "${find_in_parent_folders()}"
}
}
The root terraform.tfvars
can use the path_relative_from_include()
in combination with path_relative_to_include()
in its source
configuration to retrieve the relative terraform source code from the terragrunt configuration file:
terragrunt = {
terraform {
source = "${path_relative_from_include()}/../sources//${path_relative_to_include()}"
}
...
}
The resulting source
will be ../../sources//mysql
for mysql
module and ../../../sources//secrets/mysql
for secrets/mysql
module.
Another use case would be to add extra argument to include the common.tfvars file for all subdirectories:
terragrunt = {
terraform = {
...
extra_arguments "common_var" {
commands = [
"apply",
"plan",
"import",
"push",
"refresh"
]
arguments = [
"-var-file=${get_tfvars_dir()}/${path_relative_from_include()}/common.tfvars",
]
}
}
}
This allows proper retrieval of the common.tfvars
from whatever the level of subdirectories we have.
get_env(NAME, DEFAULT)
returns the value of the environment variable named NAME
or DEFAULT
if that environment
variable is not set. Example:
terragrunt = {
remote_state {
backend = "s3"
config {
bucket = "${get_env("BUCKET", "my-terraform-bucket")}"
}
}
}
Note that Terraform will read environment
variables that start with the
prefix TF_VAR_
, so one way to share the a variable named foo
between Terraform and Terragrunt is to set its value
as the environment variable TF_VAR_foo
and to read that value in using this get_env()
built-in function.
get_tfvars_dir()
returns the directory where the Terragrunt configuration file (by default, terraform.tfvars
) lives.
This is useful when you need to use relative paths with remote Terraform
configurations and you want those paths relative to your Terragrunt configuration
file and not relative to the temporary directory where Terragrunt downloads the code.
For example, imagine you have the following file structure:
/terraform-code
├── common.tfvars
├── frontend-app
│ └── terraform.tfvars
Inside of /terraform-code/frontend-app/terraform.tfvars
you might try to write code that looks like this:
terragrunt = {
terraform {
source = "git::[email protected]:foo/modules.git//frontend-app?ref=v0.0.3"
extra_arguments "custom_vars" {
commands = [
"apply",
"plan",
"import",
"push",
"refresh"
]
arguments = [
"-var-file=../common.tfvars", # Note: This relative path will NOT work correctly!
"-var-file=terraform.tfvars"
]
}
}
}
Note how the source
parameter is set, so Terragrunt will download the frontend-app
code from the modules
repo
into a temporary folder and run terraform
in that temporary folder. Note also that there is an extra_arguments
block that is trying to allow the frontend-app
to read some shared variables from a common.tfvars
file.
Unfortunately, the relative path (../common.tfvars
) won't work, as it will be relative to the temporary folder!
Moreover, you can't use an absolute path, or the code won't work on any of your teammates' computers.
To make the relative path work, you need to use get_tfvars_dir()
to combine the path with the folder where
the .tfvars
file lives:
terragrunt = {
terraform {
source = "git::[email protected]:foo/modules.git//frontend-app?ref=v0.0.3"
extra_arguments "custom_vars" {
commands = [
"apply",
"plan",
"import",
"push",
"refresh"
]
# With the get_tfvars_dir() function, you can use relative paths!
arguments = [
"-var-file=${get_tfvars_dir()}/../common.tfvars",
"-var-file=terraform.tfvars"
]
}
}
}
For the example above, this path will resolve to /terraform-code/frontend-app/../common.tfvars
, which is exactly
what you want.
get_parent_tfvars_dir()
returns the absolute directory where the Terragrunt parent configuration file (by default, terraform.tfvars
) lives.
This is useful when you need to use relative paths with remote Terraform configurations and you want
those paths relative to your parent Terragrunt configuration file and not relative to the temporary directory where Terragrunt downloads
the code.
This function is very similar to get_tfvars_dir() except it returns the root instead of the leaf of your terragrunt configuration folder.
/terraform-code
├── terraform.tfvars
├── common.tfvars
├── app1
│ └── terraform.tfvars
├── tests
│ ├── app2
│ | └── terraform.tfvars
│ └── app3
│ └── terraform.tfvars
terragrunt = {
terraform {
extra_arguments "common_vars" {
commands = [
"apply",
"plan",
"import",
"push",
"refresh"
]
arguments = [
"-var-file=${get_parent_tfvars_dir()}/common.tfvars"
]
}
}
}
The common.tfvars located in the terraform root folder will be included by all applications, whatever their relative location to the root.
get_terraform_commands_that_need_vars()
Returns the list of terraform commands that accept -var and -var-file parameters. This function is used when defining extra_arguments.
terragrunt = {
terraform = {
...
extra_arguments "common_var" {
commands = ["${get_terraform_commands_that_need_vars()}"]
arguments = ["-var-file=${get_aws_account_id()}.tfvars"]
}
}
}
get_terraform_commands_that_need_input()
Returns the list of terraform commands that accept -input=(true or false) parameter. This function is used when defining extra_arguments.
terragrunt = {
terraform {
# Force Terraform to not ask for input value if some variables are undefined.
extra_arguments "disable_input" {
commands = ["${get_terraform_commands_that_need_input()}"]
arguments = ["-input=false"]
}
}
}
get_terraform_commands_that_need_locking()
Returns the list of terraform commands that accept -lock-timeout parameter. This function is used when defining extra_arguments.
terragrunt = {
terraform {
# Force Terraform to keep trying to acquire a lock for up to 20 minutes if someone else already has the lock
extra_arguments "retry_lock" {
commands = ["${get_terraform_commands_that_need_locking()}"]
arguments = ["-lock-timeout=20m"]
}
}
}
Note: Functions that return a list of values must be used in a single declaration like:
commands = ["${get_terraform_commands_that_need_vars()}"]
# which result in:
commands = ["apply", "console", "destroy", "import", "plan", "push", "refresh"]
# We do not recommend using them in string composition like:
commands = "Some text ${get_terraform_commands_that_need_locking()}"
# which result in something useless like:
commands = "Some text [apply destroy import init plan refresh taint untaint]"
get_aws_account_id()
returns the AWS account id associated with the current set of credentials. Example:
terragrunt = {
remote_state {
backend = "s3"
config {
bucket = "mycompany-${get_aws_account_id()}"
}
}
}
This allows uniqueness of the storage bucket per AWS account (since bucket name must be globally unique).
It is also possible to configure variables specifically based on the account used:
terragrunt = {
terraform = {
...
extra_arguments "common_var" {
commands = ["${get_terraform_commands_that_need_vars()}"]
arguments = ["-var-file=${get_aws_account_id()}.tfvars"]
}
}
}
Auto-Init is a feature of terragrunt that makes it so that terragrunt init
does not need to be called explicitly before other terragrunt commands.
When Auto-Init is enabled (the default), terragrunt will automatically call terraform init
during other commands (e.g. terragrunt plan
) when terragrunt detects that
terraform init
has never been called, or- source needs to be downloaded, or
- the modules or remote state used by the module have changed since the previous call to
terraform init
.
As mentioned above, extra_arguments
can be configured
to allow customization of the terraform init
command.
Note that there might be cases where terragrunt does not properly detect that terraform init
needs be called.
In this case, terraform would fail. Just run terragrunt init
to correct this situation.
For some use cases, it might be desirable to disable Auto-Init.
For example, if each user wants to specify a different -plugin-dir
option to terraform init
(and therefore it cannot be put in extra_arguments
).
To disable Auto-Init, use the --terragrunt-no-auto-init
command line option or set the TERRAGRUNT_AUTO_INIT
environment variable to false
.
Disabling Auto-Init means that you must explicitly call terragrunt init
prior to any other terragrunt commands for a particular configuration.
If Auto-Init is disabled, and terragrunt detects that terraform init
needs to be called, then terragrunt will fail.
Terragrunt forwards all arguments and options to Terraform. The only exceptions are --version
and arguments that
start with the prefix --terragrunt-
. The currently available options are:
-
--terragrunt-config
: A custom path to theterraform.tfvars
file. May also be specified via theTERRAGRUNT_CONFIG
environment variable. The default path isterraform.tfvars
in the current directory (see Configuration for a slightly more nuanced explanation). This argument is not used with theapply-all
,destroy-all
,output-all
,validate-all
, andplan-all
commands. -
--terragrunt-tfpath
: A custom path to the Terraform binary. May also be specified via theTERRAGRUNT_TFPATH
environment variable. The default isterraform
in a directory on your PATH. -
--terragrunt-no-auto-init
: Don't automatically runterraform init
when other commands are run (e.g.terragrunt apply
). Useful if you want to pass custom arguments toterraform init
that are specific to a user or execution environment, and therefore cannot be specified asextra_arguments
. For example,-plugin-dir
. You must runterragrunt init
yourself in this case if needed.terragrunt
will fail if it detects thatinit
is needed, but auto init is disabled. See Auto-Init -
--terragrunt-non-interactive
: Don't show interactive user prompts. This will default the answer for all prompts to 'yes'. Useful if you need to run Terragrunt in an automated setting (e.g. from a script). May also be specified with the TF_INPUT environment variable. -
--terragrunt-working-dir
: Set the directory where Terragrunt should execute theterraform
command. Default is the current working directory. Note that for theapply-all
,destroy-all
,output-all
,validate-all
, andplan-all
commands, this parameter has a different meaning: Terragrunt will apply or destroy all the Terraform modules in the subfolders of theterragrunt-working-dir
, runningterraform
in the root of each module it finds. -
--terragrunt-source
: Download Terraform configurations from the specified source into a temporary folder, and run Terraform in that temporary folder. May also be specified via theTERRAGRUNT_SOURCE
environment variable. The source should use the same syntax as the Terraform module source parameter. If you specify this argument for theapply-all
,destroy-all
,output-all
,validate-all
, orplan-all
commands, Terragrunt will assume this is the local file path for all of your Terraform modules, and for each module processed by thexxx-all
command, Terragrunt will automatically append the path ofsource
parameter in each module to the--terragrunt-source
parameter you passed in. -
--terragrunt-source-update
: Delete the contents of the temporary folder before downloading Terraform source code into it. Can also be enabled by setting theTERRAGRUNT_SOURCE_UPDATE
environment variable totrue
. -
--terragrunt-ignore-dependency-errors
:*-all
commands continue processing components even if a dependency fails -
--terragrunt-iam-role
: Assume the specified IAM role ARN before running Terraform or AWS commands. May also be specified via theTERRAGRUNT_IAM_ROLE
environment variable. This is a convenient way to use Terragrunt and Terraform with multiple AWS accounts.
Terragrunt configuration is defined in a terraform.tfvars
file in a terragrunt = { ... }
block.
For example:
terragrunt = {
include {
path = "${find_in_parent_folders()}"
}
dependencies {
paths = ["../vpc", "../mysql", "../redis"]
}
}
Terragrunt figures out the path to its config file according to the following rules:
- The value of the
--terragrunt-config
command-line option, if specified. - The value of the
TERRAGRUNT_CONFIG
environment variable, if defined. - A
terraform.tfvars
file in the current working directory, if it exists. - If none of these are found, exit with an error.
The --terragrunt-config
parameter is only used by Terragrunt and has no effect on which variable files are loaded
by Terraform. Terraform will automatically read variables from a file named terraform.tfvars
, but if you want it
to read variables from some other .tfvars file, you must pass it in using the --var-file
argument:
terragrunt plan --terragrunt-config example.tfvars --var-file example.tfvars
Terragrunt v0.11.x and earlier defined the config in a .terragrunt file. Note that the .terragrunt format is now deprecated. You will get a warning in your logs every time you run Terragrunt with a .terragrunt file, and we will eventually stop supporting this older format.
After we released support for Terraform 0.9.x, we wrote a guide on Upgrading to Terragrunt 0.12.x.
To run Terragrunt locally, use the go run
command:
go run main.go plan
- Terragrunt uses
glide
, a vendor package management tool for golang. See the glide repo for installation instructions.
Note: The tests in the dynamodb
folder for Terragrunt run against a real AWS account and will add and remove
real data from DynamoDB. DO NOT hit CTRL+C
while the tests are running, as this will prevent them from cleaning up
temporary tables and data in DynamoDB. We are not responsible for any charges you may incur.
Before running the tests, you must configure your AWS credentials and AWS IAM policies.
To run all the tests:
go test -v -parallel 128 $(glide novendor)
To run only the tests in a specific package, such as the package remote
:
cd remote
go test -v -parallel 128
And to run a specific test, such as TestToTerraformRemoteConfigArgsNoBackendConfigs
in package remote
:
cd remote
go test -v -parallel 128 -run TestToTerraformRemoteConfigArgsNoBackendConfigs
If you set the TERRAGRUNT_DEBUG
environment variable to "true", the stack trace for any error will be printed to
stdout when you run the app.
In this project, we try to ensure that:
- Every error has a stacktrace. This makes debugging easier.
- Every error generated by our own code (as opposed to errors from Go built-in functions or errors from 3rd party libraries) has a custom type. This makes error handling more precise, as we can decide to handle different types of errors differently.
To accomplish these two goals, we have created an errors
package that has several helper methods, such as
errors.WithStackTrace(err error)
, which wraps the given error
in an Error object that contains a stacktrace. Under
the hood, the errors
package is using the go-errors library, but this may
change in the future, so the rest of the code should not depend on go-errors
directly.
Here is how the errors
package should be used:
- Any time you want to create your own error, create a custom type for it, and when instantiating that type, wrap it
with a call to
errors.WithStackTrace
. That way, any time you call a method defined in the Terragrunt code, you know the error it returns already has a stacktrace and you don't have to wrap it yourself. - Any time you get back an error object from a function built into Go or a 3rd party library, immediately wrap it with
errors.WithStackTrace
. This gives us a stacktrace as close to the source as possible. - If you need to get back the underlying error, you can use the
errors.IsError
anderrors.Unwrap
functions.
Every source file in this project should be formatted with go fmt
. There are few helper scripts and targets in the
Makefile that can help with this (mostly taken from the terraform repo):
-
make fmtcheck
Checks to see if all source files are formatted. Exits 1 if there are unformatted files.
-
make fmt
Formats all source files with
gofmt
. -
make install-pre-commit-hook
Installs a git pre-commit hook that will run all of the source files through
gofmt
.
To ensure that your changes get properly formatted, please install the git pre-commit hook with make install-pre-commit-hook
.
To release a new version, just go to the Releases Page and create a new release. The CircleCI job for this repo has been configured to:
- Automatically detect new tags.
- Build binaries for every OS using that tag as a version number.
- Upload the binaries to the release in GitHub.
See circle.yml
and _ci/build-and-push-release-asset.sh
for details.
This code is released under the MIT License. See LICENSE.txt.