Terraform
Define Sentinel policies in HCP Terraform
This topic describes how to create and manage custom policies using Sentinel policy language. For instructions about how to use pre-written Sentinel policies from the registry, refer to Run pre-written Sentinel policies.
Overview
To define a policy, create a file and declare an import
function to include reusable libraries, external data, and other functions. Sentinel policy language includes several types of elements you can import using the import
function.
Declare and configure additional Sentinel policy language elements. The details depend on which elements you want to use in your policy. Refer to the Sentinel documentation for additional information.
Note: HCP Terraform Free Edition includes one policy set of up to five policies. In HCP Terraform Plus Edition, you can connect a policy set to a version control repository or create policy set versions via the API. Refer to HCP Terraform pricing for details.
Declare an import
function
A policy can include imports that enable a policy to access reusable libraries, external data, and functions. Refer to imports in the Sentinel documentation for more details.
HCP Terraform provides four imports to define policy rules for the plan, configuration, state, and run associated with a policy check.
- tfplan - Access a Terraform plan, which is the file created as a result of the
terraform plan
command. The plan represents the changes that Terraform must make to reach the desired infrastructure state described in the configuration. - tfconfig - Access a Terraform configuration. The configuration is the set of
.tf
files that describe the desired infrastructure state. - tfstate - Access the Terraform state. Terraform uses state to map real-world resources to your configuration.
- tfrun - Access data associated with a run in HCP Terraform. For example, you could retrieve the run's workspace.
You can create mocks of these imports to use with the the Sentinel CLI mocking and testing features. Refer to Mocking Terraform Sentinel Data for more details.
HCP Terraform does not support custom imports.
Declare additional elements
The following functions and idioms will be useful as you start writing Sentinel policies for Terraform.
Iterate over modules and find resources
The most basic Sentinel task for Terraform is to enforce a rule on all resources of a given type. Before you can do that, you need to get a collection of all the relevant resources from all modules. The easiest way to do that is to copy and use a function like the following into your policies.
The following example uses the tfplan
import. You can find similar
functions that iterate over the tfconfig
and tfstate
imports
here.
import "tfplan"
import "strings"
# Find all resources of specific type from all modules using the tfplan import
find_resources_from_plan = func(type) {
resources = {}
for tfplan.module_paths as path {
for tfplan.module(path).resources[type] else {} as name, instances {
for instances as index, r {
# Get the address of the resource instance
if length(path) == 0 {
# root module
address = type + "." + name + "[" + string(index) + "]"
} else {
# non-root module
address = "module." + strings.join(path, ".module.") + "." +
type + "." + name + "[" + string(index) + "]"
}
# Add the instance to resources, setting the key to the address
resources[address] = r
}
}
}
return resources
}
Call the function to get all resources of a desired type by passing the type as a string in quotation marks:
aws_instances = find_resources_from_plan("aws_instance")
This example function does several useful things while finding resources:
- It checks every module (including the root module) for resources of the
specified type by iterating over the
module_paths
namespace. The top-levelresources
namespace is more convenient, but it only reveals resources from the root module. - It iterates over the named resources and resource
instances
found in each module, starting with
tfplan.module(path).resources[type]
which is a series of nested maps keyed by resource names and instance counts. - It uses the Sentinel
else
operator to recover fromundefined
values which would occur for modules that don't have any resources of the specified type. - It builds a flat
resources
map of all resource instances of the specified type. Using a flat map simplifies the code used by Sentinel policies to evaluate rules. - It computes an
address
variable for each resource instance and uses this as the key in theresources
map. This allows writers of Sentinel policies to print the full address of each resource instance that violate a policy, using the same address format used in plan and apply logs. Doing this tells users who see violation messages exactly which resources they need to modify in their Terraform code to comply with the Sentinel policies. - It sets the value of the
resources
map to the data associated with the resource instance (r
). This is the data that Sentinel policies apply rules against.
Validate resource attributes
Once you have a collection of resources instances of a desired type indexed by their addresses, you usually want to validate that one or more resource attributes meets some conditions by iterating over the resource instances.
While you could use Sentinel's all
and any
expressions
directly inside Sentinel rules, your rules would only report the first violation
because Sentinel uses short-circuit logic. It is therefore usually preferred to
use a for
loop outside
of your rules so that you can report all violations that occur. You can do this
inside functions or directly in the policy itself.
Here is a function that calls the find_resources_from_plan
function and
validates that the instance types of all EC2 instances being provisioned are in
a given list:
# Validate that all EC2 instances have instance_type in the allowed_types list
validate_ec2_instance_types = func(allowed_types) {
validated = true
aws_instances = find_resources_from_plan("aws_instance")
for aws_instances as address, r {
# Determine if the attribute is computed
if r.diff["instance_type"].computed else false is true {
print("EC2 instance", address,
"has attribute, instance_type, that is computed.")
} else {
# Validate that each instance has allowed value
if (r.applied.instance_type else "") not in allowed_types {
print("EC2 instance", address, "has instance_type",
r.applied.instance_type, "that is not in the allowed list:",
allowed_types)
validated = false
}
}
}
return validated
}
The boolean variable validated
is initially set to true
, but it is set to
false
if any resource instance violates the condition requiring that the
instance_type
attribute be in the allowed_types
list. Since the function
returns true
or false
, it can be called inside Sentinel rules.
Note that this function prints a warning message for every resource instance that violates the condition. This allows writers of Terraform code to fix all violations after just one policy check. It also prints warnings when the attribute being evaluated is computed and does not evaluate the condition in this case since the applied value will not be known.
While this function allows a rule to validate an attribute against a list, some
rules will only need to validate an attribute against a single value; in those
cases, you could either use a list with a single value or embed that value
inside the function itself, drop the allowed_types
parameter from the function
definition, and use the is
operator instead of the in
operator to compare
the resource attribute against the embedded value.
Write Rules
Having used the standardized find_resources_from_plan
function and having
written your own function to validate that resources instances of a specific
type satisfy some condition, you can define a list with allowed values and write
a rule that evaluates the value returned by your validation function.
# Allowed Types
allowed_types = [
"t2.small",
"t2.medium",
"t2.large",
]
# Main rule
main = rule {
validate_ec2_instance_types(allowed_types)
}
Validate multiple conditions in a single policy
If you want a policy to validate multiple conditions against resources of a
specific type, you could define a separate validation function for each
condition or use a single function to evaluate all the conditions. In the latter
case, you would make this function return a list of boolean values, using one
for each condition. You can then use multiple Sentinel rules that evaluate
those boolean values or evaluate all of them in your main
rule. Here is a
partial example:
# Function to validate that S3 buckets have private ACL and use KMS encryption
validate_private_acl_and_kms_encryption = func() {
result = {
"private": true,
"encrypted_by_kms": true,
}
s3_buckets = find_resources_from_plan("aws_s3_bucket")
# Iterate over resource instances and check that S3 buckets
# have private ACL and are encrypted by a KMS key
# If an S3 bucket is not private, set result["private"] to false
# If an S3 bucket is not encrypted, set result["encrypted_by_kms"] to false
for s3_buckets as joined_path, resource_map {
#...
}
return result
}
# Call the validation function
validations = validate_private_acl_and_kms_encryption()
# ACL rule
is_private = rule {
validations["private"]
}
# KMS Encryption Rule
is_encrypted_by_kms = rule {
validations["encrypted_by_kms"]
}
# Main rule
main = rule {
is_private and is_encrypted_by_kms
}
You can write similar functions and policies to restrict Terraform configurations using the tfconfig
import and to restrict Terraform state using the tfstate
import.
Next steps
- Group your policies into sets and apply them to your workspaces. Refer to Create policy sets for additional information.
- View results and address Terraform runs that do not comply with your policies. Refer to View results for additional information.
- You can also view Sentinel policy results in JSON format. Refer to [View Sentinel JSON results]((/terraform/cloud-docs/policy-enforcement/view-json-results) for additional information.