This Ansible playbook allows you to initialize and then deploy an entire infrastructure through the aid of Terraform, on a QEMU/KVM environment.
Terraform + Ansible
The Infrastructure as Code had considerable growth in the cloud lately. However, a separate discussion has to be done regarding the private cloud. For various reasons, companies may need to use an internal infrastructure instead of cloud ones but, unfortunately, there aren't as many solutions fsuitable or the private cloud that most of the companies needs. Our main idea was to implement a flexible and powerful solution to build an infrastructure from scratch effortlessly. Using the Ansible flexibility and the Terraform power allows users to abstract both the creation and the provisioning of the entire infrastructure, describing the whole process in a single file, easy to read and to maintain on the long run.
By our side, the need to create a single source of truth for both the infrastructure creation and provisioning, lead to that choice. As said, our objective was achievable thanks to the Ansible flexibility combined to Jinja2 simplicity that makes us capable of dynamically generating HCL files in order to leverage Terraform power and compatibility to build the infrastructure in no time.
The basic idea comes from the complexity to automate VMs deployments in a QEMU/KVM environment.
For this reason we decided to automate the deployment process as much as possible, using Ansible and Jinja2.
First of all we provided a basic HCL file (templated with Jinja2) describing a basic VM implementation. This is what is usually called IaC (Infrastructure as Code).
Then by using Terraform and its amazing libvirt provider (https://github.com/dmacvicar/terraform-provider-libvirt), we can finally deploy the resultants HCL files generated by Ansible.
The figure below describes the process in an easier way.
As you can see, we start with the templated file (terraform-vm.tf.j2
).
When Ansible runs, it generates n .tf
files, depending on the VM specified inside the inventory. This is the result of the initialization phase.
Once this task finished, the files are completed and ready to be used by Terraform.
At this time, Ansible takes those files and uses Terraform for each instance of them. Once the task is finished, the VMs previously described into the inventory, will be correctly deployed into the QEMU/KVM server(s).
Dependency | Minimum Version | Reference |
---|---|---|
Ansible | 2.9+ | https://docs.ansible.com/ |
Terraform | 0.12+ | https://www.terraform.io/docs/index.html |
Terraform Provider Libvirt | 0.6+ | https://github.com/dmacvicar/terraform-provider-libvirt/ |
Libvirt (on the target) | 1.2.14+ | https://libvirt.org/docs.html |
First of all you have to compose the inventory file in a right way. That means you have to describe the VMs you want to deploy into the server.
As you will see, there are some interesting variables you are allowed to use to properly describe your infrastructure.
Some of them are required
and some others are optional
.
Below you can see the basic structure for the inventory.
all:
vars:
...
hosts:
terraform_node:
...
hypervisor_1:
...
hypervisor_2:
...
children:
deploy:
vars:
pool_name: ...
...
children:
group_1:
hosts:
host_1:
...
vars:
...
group_2:
hosts:
host_2:
...
host_3:
...
group_3:
hosts:
host_4:
...
vars:
...
group_4:
hosts:
host_5:
...
Under the 1st vars
tag, you can specify the various hypervisors you want to use to distribute your infrastructure.
Here's a little example:
all:
hosts:
terraform_node:
ansible_host: 127.0.0.1
ansible_connection: local
vars:
...
children:
deploy:
vars:
pool_name: default
...
In the above example, we specified the uri of the QEMU/KVM server (which is going to be common among all the VMs in this specific hypervisor group),
the storage pool name for the QEMU/KVM server and the terraform node
address, which describes where Terraform is installed and where is going to being run.
Now, for each VM we want to specify some property such as the number of the cpu(s), ram, network interfaces, etc.
Here's a little example:
...
all:
hosts:
terraform_node:
ansible_host: 127.0.0.1
ansible_connection: local
hypervisor_1:
ansible_host: 127.0.0.1
ansible_connection: local
children:
deploy:
vars:
pool_name: default
disk_source: "~/VirtualMachines/centos8-terraform.qcow2"
children:
group_1:
hosts:
host_1:
os_family: RedHat
cpu: 4
memory: 8192
hypervisor: hypervisor_1
network_interfaces:
...
group_2:
hosts:
host_2:
os_family: RedHat
cpu: 2
hypervisor: hypervisor_1
host_3:
os_family: Suse
disk_source: "~/VirtualMachines/opensuse15.2-terraform.qcow2"
cpu: 4
memory: 4096
set_new_passowrd: password123
hypervisor: hypervisor_1
network_interfaces:
...
In this example, we specified 2 main groups (group_1
, group_2
) and linked the VMs to hypervisor_1
.
Those groups are made of 3 VMs (host_1
, host_2
, host_3
).
As you can see, not all the properties has been specified for each machine. This is posible due to the default variables value provided by this playbook.
Thanks to the variables hierarchy in Ansible, you can configure variables:
- Hypervisor wise
- VM group wise
- Single VM wise
This will make easier to manage large homogeneous clusters, still retaining the power of per-VM customization.
In the above example, we can see, for hypervisor_1
, the default OS for the VMs is Centos, but we specified a different one for host_3
a single OpenSuse node. Similarly for the hypervisor_2
, the default OS for the VMs is Ubuntu, but we specified Centos for the host_4
node.
This kind of configuration granularity is valid for any variable in the playbook.
You can check the default values under default/main.yml
.
Once understood how to fill the inventory file, you are ready to check all the available variables to generate your infrastructure.
These variables are required:
- ansible_host:
required
. Specifies the ip address for the VM. If not specified, a random ip is assigned. - ansible_jump_hosts:
required
if terraform_bastion_enabled isTrue
. Specifies one or more jumphost/bastions for the ansible provisioning part. - cloud_init:
optional
. Specifies if the VM uses a cloud-init image or not.False
If not specified. - data_disks:
optional
. Specifies additional disks to be added to the VM. Check disks section for internal required varibles: HERE - disk_source:
required
. Specifies the (local) path to the virtual disk you want to use to deploy the VMs. - hypervisor:
required
. Specifies on which hypervisor to deploy the Infrastructure. - network_interfaces:
required
. Specifies VM's network interfaces. Check network section for internal required variables: HERE - os_family:
required
. Specifies the OS family for the installation. Possible values are:RedHat
,Debian
,Suse
,Alpine
,FreeBSD
. - pool_name:
required
. Specifies the storage pool name where you want to deploy the VMs on the QEMU/KVM server. - ssh_password:
required
. Specifies the password to access the deployed VMs. - ssh_port:
required
. Specifies the port to access the deployed VMs. - ssh_public_key_file:
required
. Specifies the ssh public key file to deploy on the VMs. - ssh_user:
required
. Specifies the user to access the deployed VMs.
Ansible hosts required outside the deploy
group:
- terraform_node:
required
. Specifies the the machine that performs the Terraform tasks. - hypvervisor_[0-9+]:
required
. Specifies the machine/machines that works as QEMU/KVM hypervisor (at least one machine needed). The default value of 127.0.0.1 indicates that the machine that perform the Terraform tasks is the same that runs the Ansible playbook. In case the Terraform machine is not the localhost, you can specify the ip/hostname of the Terraform node. More details could be found here: HERE
These variables are optional, there are sensible defaults set up, most of them can be declared from hypervisor scope to vm-group scope and per-vm scope:
- change_passwd_command:
optional
. Specifies a different command to be used to change the user's password. If not specified the default command is used. Default:echo root:{{ set_new_password }} | chpasswd
. This variable become really useful when you are using a FreeBSD OS. - cpu:
optional
. Specifies the cpu number for the VM. If not specified, the default value is taken. Default:1
- memory:
optional
. Specifies the memory ram for the VM. If not specified, the default value is taken. Default:1024
- set_new_password:
optional
. Specifies a new password to access the Vm. If not specified, the default value (ssh_password) is taken. - terraform_custom_provisioners:
optional
. Specifies custom shell commands to run on newly created instances BEFORE ansible starts setting them up. Default""
- terrible_custom_provisioners:
optional
. Specifies custom shell commands to run AFTER terrible run is completed (for example calling specificansible pull
for each node). Default""
- vm_autoboot:
optional
. Specifies if the VM should be automatically started at boot. Default:False
- base_deploy_path:
optional
. Specifies where the Terraform files and state will be deployed, the default value is$HOME
- state_save_file:
optional
. Specifies where the output terrible state is stored, the default value isPATH_TO_THE_INVENTORY-state.tar.gz
The following section will describe some different deployment scenarios that we may tipically encounter.
As described above, the terraform_node
variable is required
.
The terraform_node
could be local or remote.
A really common scenario will have a local Terraform node. This could be declared as follows:
all:
vars:
...
hosts:
terraform_node:
ansible_host: 127.0.0.1
ansible_connection: local
hypervisor_1:
ansible_host: 127.0.0.1
ansible_connection: local
This scenario assumes that the terraform_node
is the same host that is running the Ansible playbook.
This case will ask Terraform to connect to QEMU/KVM using the uri qemu:///system
.
If you want to use a remote QEMU/KVM server instead, you can do this:
all:
vars:
...
hosts:
terraform_node:
ansible_host: 127.0.0.1
ansible_connection: local
hypervisor_1:
ansible_host: remote_kvm_machine.domain
ansible_user: root
ansible_port: 22
ansible_ssh_pass: password
This case will ask Terraform to connect to the QEMU/KVM server using the following uri: qemu+ssh://root@remote_kvm_machine.domain/system
.
This also setup the Terraform internal ssh connection to use it as a bastion host to connect to his VMs.
Also, Terraform could be separated from Ansible and be located on a remote server.
You can declare it simply by using the ansible_host
variable, as follows:
all:
vars:
...
hosts:
terraform_node:
ansible_host: remote_terraform_node.domain
ansible_connection: ssh # or paramiko or whatever NOT local
hypervisor_1:
ansible_host: remote_terraform_node.domain
ansible_connection: ssh # or paramiko or whatever NOT local
ansible_user: root
ansible_port: 22
ansible_ssh_pass: password
This assumes that the terraform_node
is the same host that is running the QEMU/KVM hypervisor.
This case will ask Terraform to connect to QEMU/KVM using the uri qemu:///system
.
The post-deployment task of this Ansible playbook, has to use a jumphost to get access to the VMs of the internal network. For this reason we need to use the terraform_node
as jumphost to reach them.
Also, if you have a remote QEMU/KVM server and a remote Terraform server, you can use them as follows:
all:
vars:
...
hosts:
terraform_node:
ansible_host: remote_terraform_node.test.com
ansible_connection: ssh # or paramiko or whatever NOT local
hypervisor_1:
ansible_host: remote_kvm_machine.domain
ansible_user: root
ansible_port: 22
ansible_ssh_pass: password
This case will ask Terraform to connect to QEMU/KVM using the uri: qemu+ssh://root@remote_kvm_machine.domain/system
.
This also setups the Terraform internal ssh connection to use it as a bastion to connect to its VMs.
Since already remote, this case will set up 2 jumphosts for Ansible, first one is the terraform_node
, the other
one is the ansible_host
.
Network declaration is mandatory and per-VM.
Declare each device you want to add inside the network_interfaces
dictionary.
Be aware that:
- the order of declaration is important
- the NAT device should always be present (unless you can control your DHCP leases for the external devices) and that should be the first device. It's an important parameter for the way the playbook has to communicate with the VM before setting up all the userspace networks.
- the
default_route
should be assigned to one interface to function properly. If not set it's equal to False.
Supported interface types:
nat
macvtap
bridge
Structure:
all:
vars:
pool_name: default
disk_source: "~/VirtualMachines/centos8-terraform.qcow2"
hosts:
terraform_node:
ansible_host: 127.0.0.1
ansible_connection: local
hypervisor_1:
ansible_host: 127.0.0.1
ansible_connection: local
children:
group_1:
hosts:
host_1:
ansible_host: 172.16.0.155
os_family: RedHat
cpu: 4
memory: 8192
hypervisor: hypervisor_1
network_interfaces:
# Nat interface, it should always be the first one you declare.
# it does not necessary have to be your default_route or main ansible_host,
# but it's important to declare it so ansible has a way to communicate with
# the VM and setup all the remaining networks.
iface_1:
name: nat # mandatory
type: nat # mandatory
ip: 192.168.122.47 # mandatory
gw: 192.168.122.1 # mandatory
dns: # mandatory
- 1.1.1.1
- 8.8.8.8
mac_address: "AA:BB:CC:11:24:68" # optional
# default_route: False
iface_2:
name: ens1p0 # mandatory
type: macvtap # mandatory
ip: 172.16.0.155 # mandatory
gw: 172.16.0.1 # mandatory
dns: # optional
- 1.1.1.1
- 8.8.8.8
default_route: True # at least one true mandatory, false is optional.
Variables explanation:
- name:
required
Specifies the name for the connection, this is important forbridge
andmacvtap
types as it will be the interface/bridge on the host on which they will be created. - type:
required
Specifies interface type, supported types are nat, macvtap, bridge. - ip:
required
Specifies the IP to assign to this interface. - gw:
required
Specifies the Gateway of this interface. - default_route:
at least one required
Specifies if this interface is the default route or not. At least one interface set as True. - dns:
required
Specifies the dns list for this interface, this is an array of IPs. - mac_address:
optional
Specifies the mac address for this interface.
The playbook will use the available IP returned from the terraform apply
command to access the machines
and use the os_family
way to setup the user-space part of the network:
- static IPs
- routes
- gateways
- DNS
After that, the playbook will set the ansible_host
variable to its original value, and proceed with
the provisioning.
This is important because it will make ansible_host
independent from the internal management interface
needed for this network bootstrap tasks, making it easily compatible with any type of role that you
want to perform after that.
During this process, virtual networks (bridges, VLANs, etc...) inside the vm will be ignored, this will improve detection of the networks we want to manage, improving compatibility with docker, k8s, nested-virtualization, etc...
This section explain how to add additional disks to the VMs.
Suppose that you want to create a VM that needs a large amount of storage, and a separated disk just to store the configurations. This will be quite simple to achieve.
The main variable you need is data_disks
, then you have to specify the disks and the related properties for each one.
If data_disks
is mentioned in your inventory, the following variables are required:
- size:
required
. Specifies the disk size expressed in GB. (eg.size: 1
means 1GB) - pool:
required
. Specifies the pool where you want to store the additional disks. - format:
require
. Specifies the filesystem format you want to apply to the disk. Available filesystems are specified below. - mount_point:
required
. Specifies the mount point you want to create for the disk, usenone
if declaring a swap disk. - encryption:
required
. Specifies the mount point of the disk. Available values could beTrue
orFalse
.
N.B. Each disk declared must have a unique name (eg. you can't use disk0
twice).
OS Family | Supported Disk Format | Encryption Supported |
---|---|---|
Debian | ext2 , ext3 , ext4 , swap |
yes |
Alpine | ext2 , ext3 , ext4 , swap |
yes |
FreeBSD | ufs , swap |
no |
RedHat | ext2 , ext3 , ext4 , xfs , swap |
yes |
Suse | ext2 , ext3 , ext4 , xfs , swap |
yes |
Let's take a look at how the inventory file is going to be fill.
all:
vars:
pool_name: default
disk_source: "~/VirtualMachines/centos8-terraform.qcow2"
hosts:
terraform_node:
ansible_host: 127.0.0.1
ansible_connection: local
hypervisor_1:
ansible_host: 127.0.0.1
ansible_connection: local
children:
group_1:
hosts:
host_1:
ansible_host: 172.16.0.155
os_family: RedHat
cpu: 4
memory: 8192
hypervisor: hypervisor_1
# Here we start to declare
# the additional disk.
data_disks:
# Here we declare the disk name
disk-storage: disk0 # Uniqe name to identify the disk unit.
size: 100 # Disk size = 100 GB
pool: default # Store the disk image into the pool = default.
format: xfs # Disk Filesystem = xfs
mount_point: /mnt/data_storage # The path where the disk is mounted, none is using swap
encryption: True # Enable disk encryption
# Here we declare the disk name
disk-swap: swp0 # Uniqe name to identify the disk unit.
size: 1 # Disk size = 1 GB
pool: default # Store the disk image into the pool = default.
format: swap # Disk Filesystem = swap
mount_point: none # The path where the disk is mounted, none if using swap
encryption: False # Does not enable disk encryption
At this time the playbook supports the most common 4 OS families for the Guests:
- Alpine
- RedHat
- RedHat7
- RedHat8
- Centos7
- Centos8
- RockyLinux
- Almalinux
- Fedora and derivatives ( untested )
- Debian
- Debian 9
- Debian 10
- Ubuntu 18
- Ubuntu 20
- Other derivatives ( untested )
- Suse
- Leap
- Thumbleweed
- Other derivatives ( untested )
- FreeBSD
- FreeBSD 12.x
- FreeBSD 13.x
- Other derivatives ( untested )
This means you'll be able to generate the infrastructure using ONLY the OS listed above.
Hypervisor OS is agnostic, as long as requirements are met.
Before using Terrible, the following system dependencies needs to be installed: dependencies.
Use the following command to satisfy the project dependencies:
pip3 install --user -r requirements.txt
To avoid boring dependencies installation to make Terrible works and speed up your infrastructure deployment, we provided a Dockerfile
to build yourself a minimal image with all you need.
We use a debian:buster-slim
image to have a compact system, fully compatibile with all the required tools. The container image uses the latest Terrible tag's release.
The minimum packages required to run the container image is Docker (or Podman) and QEMU/KVM installed on the system.
If you are a lazy person (just like us), you can directly pull the latest image release from DockerHub.
docker pull 89luca89/terrible:latest
To build the image, instead, type the following command:
docker build -t terrible .
This will take some time, grab a cup of coffee and wait.
Once you've built the image, you're ready to run it as in the example below:
docker run \
-it \
--rm \
-v /var/run/libvirt/libvirt-sock:/var/run/libvirt/libvirt-sock \
-v ./inventory-test.yml:/terrible/inventory-test.yml \
-v /path/to/vm/images/:/opt/ \
-v ~/.ssh/:/root/.ssh/ \
89luca89/terrible
N.B. If you are using RHEL, CentOS or Fedora you need to add the --privileged
flag because otherwise SELinux does not allow it to access the libvirt socket.
N.B. If you are using your local QEMU/KVM instance, remember to add --net=host
to the command.
Notes:
-
The volume
/var/run/libvirt/libvirt-sock
is mandatory if you want to run Terrible locally (a local QEMU/KVM instance). In this way you'll directly interact with the QEMU/KVM api, provided by the system. -
The volume
./inventory-test.yml
has to include the inventory file inside the container, to deploy the infrastructure. -
The volume
~/VirtualMachines/
has to include theqcow2
images inside the container to deploy them. -
The volume
~/.ssh
has to include your ssh keys into the container to deploy them inside the infrastructure machines.
To speed up your deployment process, we made our Packer template files available.
The other repository could be found here: packer-terraform-kvm.
Once composed the inventory file, it's time to run your playbook.
To pull up infrastructure:
ansible-playbook -i inventory.yml -u root main.yml
To validate the inventory file:
ansible-playbook -i inventory.yml -u root main.yml --tags validate
To pull down infrastructure (maintaining the resources in place):
ansible-playbook -i inventory.yml -u root main.yml --tags destroy
To completely delete the infrastructure:
ansible-playbook -i inventory.yml -u root main.yml --tags purge
Based on your inventory, the complete state of the infrastructure (TF files, TF states, LUKS keys etc...)
will be written to ${INVENTORY_NAME}-state.tar.gz
this file is essential to keep track of the
infrastructure state.
You can (and should) save this state file to keep track of the infrastructure complete state, the *.tar.gz will be restored and saved on each run.
- Luca Di Maio [email protected]
- Alessio Greggi [email protected]
- GNU GPLv3, See LICENSE file.