Notes for my Cloud certifications.
Infrastructure as Code it is the process of managing infrastructure in a file or files rather than manually configuring resources in a user interface. A resource in this instance is any piece of infrastructure in a given environment, such as a virtual machine, security group, network interface, etc.
Terraform is a tool for building, changing, and versioning infrastructure safely and efficiently. Terraform can manage existing and popular service providers as well as custom in-house solutions.
Configuration files describe to Terraform the components needed to run a single application or your entire datacenter. Terraform generates an execution plan describing what it will do to reach the desired state, and then executes it to build the described infrastructure. As the configuration changes, Terraform is able to determine what changed and create incremental execution plans which can be applied.
The infrastructure Terraform can manage includes low-level components such as compute instances, storage, and networking, as well as high-level components such as DNS entries, SaaS features, etc.
Strings, Numbers, Boolean, List, or Maps. We can define a default
value, example
variable "vpcname" {
type = string
default = "myvpc"
}
variable "enabled" {
default = true
}
variable "sshport" {
type = number
default = 22
}
Note: Number or integers don’t need double quotes, but Terraform automatically converts number and bool values to strings when needed. For example 5 and “5” both are correct.
List is the same than an array. We can store multiple values Remember the first value is the 0 position. For example to access the 0 position is var.mylist[0]
variable "mylist" {
type = list(string)
default = ["Value1", "Value2"]
}
Is a Key:Value pair. We use the key to access to the value
variable "mymap" {
type = map
default = {
Key1 = "Value1"
Key2 = "Value2"
}
}
Important: For example, if we need to access the value of Key1 (Value1) we can using the next example var.mymap["Key1"]
Note: Remember, we use [ ] for list, and we use { } for maps
Is useful to permit the user to manually set a variable when we run Terraform plan, we can add a “description” and when we run a plan shows a message
It is useful to permit the user to set a variable manually when we run Terraform plan, we can add a “description,” and when we run a plan, it shows a message
variable "vpc_name" {
type = string
description = "Set VPC name"
}
terraform plan example:
var.inputname
Set VPC name
Enter a value:
Is about the resource we created, when we run the apply
we can see the value, not in the plan
because in the next case for example, we need first the VPC for know the vpc.id
output "vpc_id" {
value = "aws_vpc.myvpc.id"
}
If we run a apply
we can see the next message:
Apply complete!
Outputs:
vpcid = vpc-099d9099f5faec2d9
A local value assigns a name to an expression, allowing it to be used multiple times within a module without repeating it.
Comparing modules to functions in a traditional programming language: if input variables are analogous to function arguments and outputs values are analogous to function return values, then local values are comparable to a function’s local temporary symbols.
Note: For brevity, local values are often referred to as just “locals” when the meaning is clear from context.
Declaring a local value:
A set of related local values can be declared together in a single locals
block
locals {
service_name = "forum"
owner = "Community Team"
}
The expressions assigned to local value names can either be simple constants like the above, allowing these values to be defined only once but used many times, or they can be more complex expressions that transform or combine values from elsewhere in the module:
When to use local values:
Local values can be helpful to avoid repeating the same values or expressions multiple times in a configuration, but if overused they can also make a configuration hard to read by future maintainers by hiding the actual values used.
Use local values only in moderation, in situations where a single value or result is used in many places and that value is likely to be changed in future. The ability to easily change the value in a central place is the key advantage of local values.
We can create an export with our variable before execute terraform plan
, and overwrite the value on the .tf files, for example export TF_VAR_vpcname=envvpc
. This is useful for pass secrets or sensitive information in a secure form.
Another way to set variables is by using the command-line, for example terraform plan -var="vpcname=cliname"
Passing variables inside a file, this is possible create a file called terraform.tfvars
this file can be in a yaml or json notation, and is very simple, and also we can add maps, for example:
vpcname = "tfvarsname"
port = 22
policy = {
test = 1
debug = "true"
}
Note: The terraform.tfvars
file is used to define variables and the .tf
file declare that the variable exists.
Link: https://amazicworld.com/difference-between-variable-tf-and-variable-tfvars-in-terraform
This is for example using a file called dev.auto.tfvars
(is the next file that look after look in the terraform.tfvars)
We can create a specified *.tvars
file and load for example with terraform plan
, this is very useful to settings variables for different environments.
terraform plan -var-file=prod.tfvars
terraform.tfvars.json
terraform.tfvars
Note: there is no mention of .tf file declaration in there, this is because variables declared in .tf files are concatenated into a single entity consisting of your variables.tf your main.tf and your output.tf files before being processed by Terraform. Hence this declaration have highest precedence in order of application.
The required_version
setting can be used to constrain which versions of the Terraform CLI can be used with your configuration. If the running version of Terraform doesn’t match the constraints specified, Terraform will produce an error and exit without taking any further actions.
terraform {
required_version = ">= 0.12"
}
The value for required_version
is a string containing a comma-separated list of constraints. Each constraint is an operator followed by a version number, such as > 0.12.0
. The following constraint operators are allowed:
=
(or no operator): exact version equality!=
: version not equal>
, >=
, <
, <=
: version comparison, where “greater than” is a larger version number~>
: pessimistic constraint operator, constraining both the oldest and newest version allowed. For example, ~> 0.9
is equivalent to >= 0.9, < 1.0
, and ~> 0.8.4
, is equivalent to >= 0.8.4, < 0.9
We can also specified a provider version requirement
provider "aws" {
region = "us-east-1"
version = ">= 2.9.0"
}
Link: https://www.terraform.io/docs/configuration/terraform.html#specifying-a-required-terraform-version
A provider is responsible for understanding API interactions and exposing resources. If an API is available, you can create a provider. A provider user a plugin. In order to make a provider available on Terraform, we need to make a terraform init
, this commands download any plugins we need for our providers. If for example we need to copy the plugin directory manually, we can do it, moving the files to .terraform.d/plugins
Note: Using terraform providers
command we can view the specified version constraints for all providers used in the current configuration
Example configuration:
terraform {
required_providers {
aws = "~> 2.7"
}
}
Check:
$ terraform providers
.
└── provider.aws ~> 2.7
When terraform init
is re-run with providers already installed, it will use an already-installed provider that meets the constraints in preference to downloading a new version. To upgrade to the latest acceptable version of each provider, run terraform init -upgrade
. This command also upgrades to the latest versions of all Terraform modules.
We can use for example multiple AWS providers with different regions, for this we need to create an alias
and on the resource creation we need to specified the provider. For example
provider "aws" {
region = "us-east-1"
}
provider "aws" {
region = "us-west-1"
alias = "ireland"
}
resource "aws_vpc" "irlvpc" {
cidr_block = "10.0.0.0/16"
provider = "aws.ireland"
}
Provisioners can be used to model specific actions on the local machine or on a remote machine in order to prepare servers or other infrastructure objects for service.
Note: Provisioners should only be used as a last resort. For most common situations there are better alternatives.
Example:
resource "aws_instance" "web" {
# ...
provisioner "local-exec" {
command = "echo The server's IP address is ${self.private_ip}"
}
}
The local-exec
provisioner requires no other configuration, but most other provisioners must connect to the remote system using SSH or WinRM.
By default, provisioners run when the resource they are defined within is created. Creation-time provisioners are only run during creation, not during updating or any other lifecycle. They are meant as a means to perform bootstrapping of a system. If a creation-time provisioner fails, the resource is marked as tainted. A tainted resource will be planned for destruction and recreation upon the next terraform apply
If when = "destroy"
is specified, the provisioner will run when the resource it is defined within is destroyed.
resource "aws_instance" "web" {
# ...
provisioner "local-exec" {
when = "destroy"
command = "echo 'Destroy-time provisioner'"
}
}
Destroy provisioners are run before the resource is destroyed. If they fail, Terraform will error and rerun the provisioners again on the next terraform apply
Note: By default, a defined provisioner is a creation-time provisioner. You must explicitly define a provisioner to be a destroy-time provisioner
With Terraform the plugins have 2 options to do the job:
One example of local-exec is create a ssh key in our machine.
resource "null_resource" "generate-sshkey" {
provisioner "local-exec" {
command = "yes y | ssh-keygen -b 4096 -t rsa -C 'terraform-vsphere-kubernetes' -N '' -f ${var.virtual_machine_kubernetes_controller.["private_key"]}"
}
}
Another example for local-exec is execute a script for Download Lambda dependencies, and after that, make a zip.
One example for remote-exec is from the key create previously, we can configure on a deployed virtual machine
provisioner "remote-exec" {
inline = [
"mv /tmp/authorized_keys /root/.ssh/authorized_keys",
"chmod 600 /root/.ssh/authorized_keys",
]
connection {
type = "${var.virtual_machine_template.["connection_type"]}"
}
}
Links:
3 types of users, the workflow change according to the user
Individual
Team
Terraform Cloud
development
environment (statefiles, variables and secrets on Terrafom Cloud)The terraform init
command is used to initialize a working directory containing Terraform configuration files. It is safe to run this command multiple times, , this command will never delete your existing configuration or state. During init, the root configuration directory is consulted for backend configuration and the chosen backend is initialized using the given configuration settings.
Link: https://www.terraform.io/docs/commands/init.html
The terraform validate
command validates the configuration files in a directory, referring only to the configuration and not accessing any remote services such as remote state, provider APIs, etc.
Validate runs checks that verify whether a configuration is syntactically valid and internally consistent, regardless of any provided variables or existing state.
It is thus primarily useful for general verification of reusable modules, including correctness of attribute names and value types.
It is safe to run this command automatically, for example as a post-save check in a text editor or as a test step for a re-usable module in a CI system.
Note: Validation requires an initialized working directory with any referenced plugins and modules installed.
Link: https://www.terraform.io/docs/commands/validate.html
The terraform plan
command is used to create an execution plan. Terraform performs a refresh, unless explicitly disabled, and then determines what actions are necessary to achieve the desired state specified in the configuration files.
Link: https://www.terraform.io/docs/commands/plan.html
The terraform apply
command is used to apply the changes required to reach the desired state of the configuration, or the pre-determined set of actions generated by a terraform plan
execution plan.
Link: https://www.terraform.io/docs/commands/apply.html
The terraform destroy
command is used to destroy the Terraform-managed infrastructure.
Link: https://www.terraform.io/docs/commands/destroy.html
The terraform fmt
command is used to rewrite Terraform configuration files to a canonical format and style. The canonical format may change in minor ways between Terraform versions, so after upgrading Terraform it is recommended to proactively run fmt
The terraform taint
command manually marks a Terraform-managed resource as tainted, forcing it to be destroyed and recreated on the next apply. Taint force the recreation. This command will not modify infrastructure, but does modify the state file in order to mark a resource as tainted. Once a resource is marked as tainted, the next plan will show that the resource will be destroyed and recreated and the next apply will implement this change.
Forcing the recreation of a resource is useful when you want a certain side effect of recreation that is not visible in the attributes of a resource. For example: re-running provisioners will cause the node to be different or rebooting the machine from a base image will cause new startup scripts to run.
Example:
$ terraform taint aws_vpc.myvpc
The resource aws_vpc.myvpc in the module root has been marked as tainted.
Another example if we want taint the resource “aws_instance” “baz” resource that lives in module bar which lives in module foo.
terraform taint module.foo.module.bar.aws_instance.baz
Link: https://www.terraform.io/docs/internals/resource-addressing.html
The terraform untaint
command manually unmark a Terraform-managed resource as tainted, restoring it as the primary instance in the state.
Note: This command will not modify infrastructure, but does modify the state file in order to unmark a resource as tainted.
$ terraform untaint aws_vpc.myvpc
Resource aws_vpc.myvpc2 has been successfully untainted.
The terraform import
command is used to import existing resources into Terraform.
Import will find the existing resource from ID and import it into your Terraform state at the given ADDRESS.
ADDRESS must be a valid resource address. Because any resource address is valid, the import command can import resources into modules as well directly into the root of your state.
ID is dependent on the resource type being imported. For example, for AWS instances it is the instance ID (i-abcd1234
) but for AWS Route53 zones it is the zone ID (Z12ABC4UGMOZ2N
).
Usage: terraform import [options] ADDRESS ID
Example:
$ terraform import aws_vpc.vpcimport vpc-06f0e46d612
Note: terraform import
command can import resources directly into modules
Link: https://www.terraform.io/docs/commands/import.html
The terraform show
command is used to provide human-readable output from a state or plan file. This can be used to inspect a plan to ensure that the planned operations are expected, or to inspect the current state as Terraform sees it.
Usage: terraform show [options] [path]
You may use show
with a path to either a Terraform state file or plan file. If no path is specified, the current state will be shown.
The terraform workspace
command is used to manage workspaces. It is useful to split and separate the statefiles.
This command is a container for further subcommands such as list
, select
, new
, delete
and show
Usage: terraform workspace <subcommand> [options] [args]
If we never create a workspace we use the default workspace
# terraform workspace list
* default
Note: For local state, Terraform stores the workspace states in a directory called terraform.tfstate.d
. This directory should be treated similarly to local-only terraform.tfstate
Note: Terraform Cloud and Terraform CLI both have features called “workspaces,” but they’re slightly different. CLI workspaces are alternate state files in the same working directory; they’re a convenience feature for using one configuration to manage multiple similar groups of resources.
The terraform workspace new
command is used to create a new workspace.
$ terraform workspace new dev
Created and switched to workspace "dev"!
You're now on a new, empty workspace. Workspaces isolate their state,
so if you run "terraform plan" Terraform will not see any existing state
for this configuration.
Now, if we execute a terraform plan
in our environment, the plan will try to show many resources to create, because is a different state file.
The terraform workspace show
command is used to output the current workspace.
$ terraform workspace show
dev
The terraform workspace select
command is used to choose a different workspace to use for further operations. First we need to execute a terraform workspace list
to know the workspaces names.
$ terraform workspace select default
Switched to workspace "default".
The terraform workspace delete
command is used to delete an existing workspace.
$ terraform workspace delete dev
Deleted workspace "dev"!
The terraform state list
command is used to list resources within a Terraform state
The command will list all resources in the state file matching the given addresses (if any). If no addresses are given, all resources are listed.
Example list all resources:
$ terraform state list
aws_instance.foo
aws_instance.bar[0]
aws_instance.bar[1]
module.elb.aws_elb.main
Example Filtering by Resource
$ terraform state list aws_instance.bar
aws_instance.bar[0]
aws_instance.bar[1]
Link: https://www.terraform.io/docs/commands/state/list.html
The terraform state pull
command is used to manually download and output the state from remote state. This command also works with local state (but is not very useful because we can see the local file)
This command will download the state from its current location and output the raw format to stdout.
This is useful for reading values out of state (potentially pairing this command with something like jq). It is also useful if you need to make manual modifications to state.
The terraform state mv
command is used to move items in a Terraform state. This command can move single resources, single instances of a resource, entire modules, and more. This command can also move items to a completely different state file, enabling efficient refactoring.
Usage: terraform state mv [options] SOURCE DESTINATION
This can be used for simple resource renaming, moving items to and from a module, moving entire modules, and more. And because this command can also move data to a completely new state, it can also be used for refactoring one configuration into multiple separately managed Terraform configurations.
Example:
terraform state mv 'packet_device.worker' 'packet_device.helper'
Link: https://www.terraform.io/docs/commands/state/mv.html
The terraform state rm
command is used to remove items from the Terraform state. This command can remove single resources, single instances of a resource, entire modules, and more.
Usage: terraform state rm [options] ADDRESS...
Items removed from the Terraform state are not physically destroyed. Items removed from the Terraform state are only no longer managed by Terraform. For example, if you remove an AWS instance from the state, the AWS instance will continue running, but terraform plan
will no longer see that instance.
There are various use cases for removing items from a Terraform state file. The most common is refactoring a configuration to no longer manage that resource (perhaps moving it to another Terraform configuration/state).
Example remove a resource:
$ terraform state rm 'packet_device.worker'
Example remove a module:
$ terraform state rm 'module.foo'
Link: https://www.terraform.io/docs/commands/state/rm.html
A module is a simple directory that contains other .tf files. Using modules we can make the code reusable. Modules are local or remote.
Is the place to find modules, theses modules are verified by Hashicorp
Link: https://registry.terraform.io/
For make modules inputs we use inputs variables. Example module code:
variable "dbname" {
type = string
}
resource "aws_instance" "myec2db" {
ami = "ami-01a6e"
tags = {
Name = var.dbname
}
}
Call to the module example:
module "dbserver" {
source = "./db"
dbname = "mydbserver"
}
Module outputs are very similar to module inputs, an example in a module output:
output "privateip" {
value = aws_instance.myec2db.private_ip
}
When we use a module with an output, to use the output we need to specified in the call to our module, for example:
module "dbserver" {
source = "./db"
dbname = "mydbserver"
}
output "dbprivateip" {
value = module.dbserver.privateip
}
Terraform allow having child modules, modules within modules. Basically is a directory with tf files, with others directories with others sub modules. After add a subdirectory, remember to execute again terraform init
Within top-level block constructs like resources, expressions can usually be used only when assigning a value to an argument using the name = expression
form. This covers many uses, but some resource types include repeatable nested blocks in their arguments.
You can dynamically construct repeatable nested blocks like setting
using a special dynamic
block type, which is supported inside resource
, data
, provider
, and provisioner
blocks:
resource "aws_elastic_beanstalk_environment" "tfenvtest" {
name = "tf-test-name"
application = "${aws_elastic_beanstalk_application.tftest.name}"
solution_stack_name = "64bit Amazon Linux 2018.03 v2.11.4 running Go 1.12.6"
dynamic "setting" {
for_each = var.settings
content {
namespace = setting.value["namespace"]
name = setting.value["name"]
value = setting.value["value"]
}
}
}
A dynamic
block acts much like a for
expression, but produces nested blocks instead of a complex typed value. It iterates over a given complex value, and generates a nested block for each element of that complex value.
Link: https://www.terraform.io/docs/configuration/expressions.html
The difference between a tuple and a list, is on the list we need to specified one type (string or numbers), and using tuple we can use multiple data-types
variable "mytuple" {
type = tuple([string, number, string])
default = ["cat", 1, "dog"]
}
Is the same case of tuples with list, but in this case is with maps. Using Objects we can use multiple data-types
variable "myobject" {
type = object({name = string, port = list(number)})
default = {
name = "TJ"
port = [22, 25, 80]
}
}
Note: Using objects and tuples allows us to have multiple values of several distinct types to be grouped as a single value.
Explicitly specifying a dependency is only necessary when a resource relies on some other resource’s behavior but doesn’t access any of that resource’s data in its arguments.
resource "aws_instance" "example" {
ami = "ami-a1b2c3d4"
instance_type = "t2.micro"
depends_on = [aws_iam_role_policy.example]
}
The depends_on
meta-argument, if present, must be a list of references to other resources in the same module.
Data Sources are the way Terraform can query AWS and return results (Api request to get information)
Use of data sources allows a Terraform configuration to make use of information defined outside of Terraform, or defined by another separate Terraform configuration.
For example we can information to an EC2 created on AWS without being created using Terraform,
Example using a data source to know the AZ of an Instance created without Terraform, a print on the output command.
# Find the latest available AMI that is tagged with Component = "DB server"
data "aws_instance" "dbsearch" {
filter {
name = "tag:Name"
values = ["DB server"]
}
}
output "dbserver" {
value = data.aws_instance.dbsearch.availability_zone
}
A data block request that Terraform read from a given data source and export the result under the give local name.
Note: Data source attributes are interpolated with the general syntax data.TYPE.NAME.ATTRIBUTE. The interpolation for a resource is the same but without the data. prefix (TYPE.NAME.ATTRIBUTE).
Link: https://www.terraform.io/docs/providers/aws/d/instance.html
The Terraform language includes a number of built-in functions that you can call from within expressions to transform and combine values. The general syntax for function calls is a function name followed by comma-separated arguments in parentheses:
max(5, 12, 9)
Note: The Terraform language does not support user-defined functions, and so only the functions built in to the language are available for use.
A very useful function is the file
function, using that, we can read the contents of a file and returns them as a string. Another important function is the flatten
function, this takes a list and replaces any elements that are list with a flattened sequence of the list contents.
The last important function is lookup
, this retrieves the value of a single element from a map, given its key. If the given key does not exist, a the given default value is returned instead.
lookup(map, key, default)
Examples:
> lookup({a="ay", b="bee"}, "a", "what?")
ay
> lookup({a="ay", b="bee"}, "c", "what?")
what?
Links:
In the case of using AWS provider the best practice for store credentials is having the keys in the AWS config file .aws/credentials
, and not having the credentials in the Terraform code
Sentinel is an embedded policy-as-code framework integrated with the HashiCorp Enterprise products. It enables fine-grained, logic-based policy decisions, and can be extended to use information from external sources.
Vault allows you to manage secrets and protect sensitive data. Secure, store and tightly control access to tokens, passwords, certificates, encryption keys for protecting secrets and other sensitive data using a UI, CLI, or HTTP API.
The following Terraform files should be ignored by Git when committing code to a repo:
The terraform.tfstate
or .auto.tfvars
files contains the terraform state of a specific environment and doesn’t need to be preserved in a repo. The terraform.tfvars
file may contain sensitive data, such as passwords or IP addresses of an environment that you may not want to share with others.
The local backend stores state on the local filesystem, locks that state using system APIs, and performs operations locally.
terraform {
backend "local" {
path = "relative/path/to/terraform.tfstate"
}
}
You do not need to specify every required argument in the backend configuration. Omitting certain arguments may be desirable to avoid storing secrets, such as access keys, within the main configuration. When some or all of the arguments are omitted, we call this a partial configuration.
With a partial configuration, the remaining configuration arguments must be provided as part of the initialization process. There are several ways to supply the remaining arguments:
init
command line. To specify a file, use the -backend-config=PATH
option when running terraform init
init
command line.The terraform refresh
command is used to reconcile the state Terraform knows about (via its state file) with the real-world infrastructure. This can be used to detect any drift from the last-known state, and to update the state file.
This does not modify infrastructure, but does modify the state file. If the state is changed, this may cause changes to occur during the next plan or apply.
Usage: terraform refresh [options] [dir]
For example, if we change some configuration using the web console, we need to do:
$ terraform refresh
$ terraform plan
refresh
Is good to sync changes, in some cases is better to use terraform import
depending of the complexity
Link: https://www.terraform.io/docs/commands/refresh.html
Stores the state as a given key in a given bucket on Amazon S3. This backend also supports state locking and consistency checking via Dynamo DB, which can be enabled by setting the dynamodb_table
field to an existing DynamoDB table name. A single DynamoDB table can be used to lock multiple remote state files. Terraform generates key names that include the values of the bucket
and key
variables.
Example:
terraform {
backend "s3" {
bucket = "mybucket"
key = "state/terraform.tfstate"
region = "us-east-1"
}
}
Note: This assumes we have a bucket created called mybucket
. The Terraform state is written to the key state/terraform.tfstate
.
Important: If we have a local state, and after that we change to the S3 backend, when we execute terraform init
the system ask us if we want to copy existing state to the new backend.
Similar to if we delete a remote backend from the configuration, when we execute the re-initialization, Terraform will ask if we would like to migrate our state back down to normal local state.
Link: https://www.terraform.io/docs/backends/types/s3.html
If we want to change from S3 backend to Local backend, only we need to do terraform destroy
after that delete backend.tf
file, and run terraform init
When we use Terraform is only allowed one backend.
The state cannot store secrets, for that reason we need to encrypt at rest.
Manually unlock the state for the defined configuration.
This will not modify your infrastructure. This command removes the lock on the state for the current configuration. The behavior of this lock is dependent on the backend being used. Local state files cannot be unlocked by another process.
Usage: terraform force-unlock LOCK_ID [DIR]
This is useful for example when another person write the remote state file, and something happening and the state file is lock, and we need to release.
Link: https://www.terraform.io/docs/commands/force-unlock.html
If we need the best solution for encryption and backups, the answer is Terraform Cloud. Terraform Cloud encrypt the state file at rest, and also encrypt using TLS.
When we use remote states, Terraform save all the temporal information on memory, nothing persistent on disk, this is another Terraform security implementation.
Backend cannot have any interpolations or use any variables. This need to be manually hardcoded
The terraform state push
command is used to manually upload a local state file to remote state. This command also works with local state.
Usage: terraform state push [options] PATH
Link: https://www.terraform.io/docs/commands/state/push.html
Note: Backend that support state lockings: Azurerm, Consul, S3
Terraform has detailed logs which can be enabled by setting the TF_LOG
environment variable to any value. This will cause detailed logs to appear on stderr.
Is not about to Terraform Client Debugging, panic errors, go errors, etc. Is useful to provide the logs to Hashicorp.
export TF_LOG=TRACE
You can set TF_LOG
to one of the log levels TRACE
, DEBUG
, INFO
, WARN
or ERROR
to change the verbosity of the logs. TRACE
is the most verbose and it is the default if TF_LOG
is set to something other than a log level name.
Note: When TF_LOG_PATH
is set, TF_LOG
must be set in order for any logging to be enabled, and TF_LOG_PATH
point to a specific file (not directory), for example TF_LOG_PATH=./terraform.log
Link: https://www.terraform.io/docs/internals/debugging.html
Terraform Cloud (TFC) is a free to use, self-service SaaS platform that extends the capabilities of the open source Terraform CLI and adds collaboration and automation features.
Terraform Cloud enables connecting to common VCS platforms (GitHub, GitLab, Bitbucket) and triggering Terraform runs (plan and apply) from changes to configuration within the VCS. TFC manages state for the user, including keeping a history of changes. Terraform Cloud exposes an HTTP API that anyone can integrate with to build more automation around infrastructure change.
First we need to create an account on https://app.terraform.io/signup/account and create a new Git repository, and upload our .tf
files.
After that on Terraform Cloud web page we need to create an Organization, only we need to specified the name, and one email address, after that we can connect to our Git repository (Github, Gitlab, Bitbucket and Azure DevOps are available), also we need to authorize Terraform Cloud in our Git repository, is only one click.
Also we can implement a Private module registry in Terraform Cloud.
Now we need to create a Workspace on Terraform Cloud (is different to the Workspace on Terraform), this is for create a separate environment, for example dev, prod, etc.
Right now we need to Configure Variables, because we used AWS provider, we need to configure the AWS credentials (Also we can configure using Vault)
For the last, we need to configure a Queue Plan, this allow us to execute a Terraform plan
after this complete, we can Confirm & Apply
Note: The remote backend stores Terraform state and may be used to run operations in Terraform Cloud. When using full remote operations, operations like terraform plan
or terraform apply
can be executed in Terraform Cloud’s run environment, with log output streaming to the local terminal.
Note: Workspaces, managed with the terraform workspace
command, aren’t the same thing as Terraform Cloud’s workspaces. Terraform Cloud workspaces act more like completely separate working directories; CLI workspaces are just alternate state files.
Note: Terraform Cloud always encrypts state at rest and protects it with TLS in transit.
If we want to do a Destroy, we only need to click on the option “Queue destroy plan”
Component | Local Terraform | Terraform Cloud |
---|---|---|
Terraform Configuration | On Disk | In linked version control repository, or periodically updated via API/CLI |
Variable values | As .tfvars file, as CLI arguments, or in shell environment | In workspace |
State | On disk or in remote backend | In workspace |
Credential and secrets | In shell environment or entered at prompts | In workspace, stored as sensitive variables |
Some paid features are Roles & Team management, Cost Estimation and Sentinel.
Up to 5 users we can have the free tier, with VCS integration, Workspace Management, Secure Variable Storage, Remote Runs & Applies, Full API Coverage and Private Module Registry.
Link: https://www.hashicorp.com/products/terraform/pricing/
Terraform Enterprise is a hosted version of Terraform Cloud, but using Terraform Enterprise we can have the following features:
SAML/SSO
Audit Logs
Private Network Connectivity
Clustering
Sentinel, VCS Integration are offered also in Terraform Cloud. Everything that is in Terraform cloud is already included in Terraform Enterprise.
A Terraform Enterprise install that is provisioned on a network that does not have Internet access is generally known as an air-gapped install. These types of installs require you to pull updates, providers, etc. from external sources vs. being able to download them directly.
Terraform Enterprise requires a PostgresSQL for a clustered deployment.
Some Backends supported: Terraform Enterprise, Consul, S3, Artifactory.
Terraform Cloud supports the following VCS providers: GitHub, Gitlab, Bitbucket and Azure DevOps
The existence of a provider plugin found locally in the working directory does not itself create a provider dependency. The plugin can exist without any reference to it in Terraform configuration.
Function index
finds the element index for a given value in a list starting with index 0.
HashiCorp style conventions suggest you that align the equals sign for consecutive arguments for easing readability for configurations
ami = "abc123"
instance_type = "t2.micro"
Terraform can limit the number of concurrent operations as Terraform walks the graph using the -parallelism=n
argument. The default value for this setting is 10
. This setting might be helpful if you’re running into API rate limits.
HashiCorp style conventions state that you should use 2 spaces between each nesting level to improve the readability of Terraform configurations.
Terraform supports the #, //, and /../ for commenting Terraform configuration files. Please use them when writing Terraform so both you and others who are using your code have a full understanding of what the code is intended to do.
The terraform console
command provides an interactive console for evaluating expressions such interpolations. https://www.terraform.io/docs/commands/console.html