Commonly used IaC languages

There are several commonly used IaC languages. Below are some of the most popular ones.

Terraform is a popular open-source tool and Domain-Specific Language (DSL) for building, changing, and versioning infrastructure. Terraform is cloud agnostic, which means that it has a generic syntax can be used to configure a wide range of cloud providers and infrastructure platforms, including AWS, Azure, GCP, Kubernetes, Red Hat OpenShift, databases like MySQL and PostgreSQL, firewalls, and more. But it must be noted that each platform needs its own configuration details – in Terraform, configuring an EC2 VM in AWS is done differently than configuring a VM in Azure.

As an example, the following Terraform code creates a virtual machine in Azure:

Resource "azurerm_network_interface" "mynic" {
   name                = "myvm1-nic"
   location            = "northeurope"
   resource_group_name = "MyRG" 

   ip_configuration {

     name      = "ipconfig1"
     subnet_id = azurerm_subnet.frontendsubnet.id

     private_ip_address_allocation = "Dynamic"
   }
 }

Resource "azurerm_windows_virtual_machine" "example" {
   name                  = "myvm1"  
   location              = "northeurope"
   resource_group_name   = "MyRG"
   network_interface_ids = [azurerm_network_interface.mynic.id]
   size                  = "Standard_B1s"
   admin_username        = "adminuser" 
   admin_password        = "Password123!"  

   source_image_reference {
     publisher = "MicrosoftWindowsServer"
     offer     = "WindowsServer"
     sku       = "2019-Datacenter"
     version   = "latest"
   }

   os_disk {
     caching            = "ReadWrite"
     storage_account_type = "Standard_LRS"
   }
 }

As a comparison, the following Terraform code creates an EC2 virtual machine in AWS:

 resource "aws_instance" "example" {
  ami = "ami-0be2609ba883822ec" # Windows Server 2019 Base
  instance_type = "t2.micro"
  key_name = "my_keypair"
  vpc_security_group_ids = [aws_security_group.allow_rdp.id]
  subnet_id = "subnet-12345678"
  associate_public_ip_address = true
  private_ip = "10.0.1.10" # Private IP address of the instance
  user_data = <<-EOF
    <powershell>
    # Set the administrator password
    net user Administrator <password>
    </powershell>
    EOF
  }
}

 As you can see, the syntax is the same, but the way the virtual machine is created is different between the cloud providers.

Azure Resource Manager (ARM) templates are JSON files that describe Azure infrastructure resources. ARM templates provide a declarative syntax for defining the infrastructure resources and their dependencies, as well as the configuration settings for each resource.

Azure Bicep is a Domain-Specific Language (DSL) for Microsoft Azure. Bicep builds on top of ARM templates and provides an abstraction layer that allows developers to write code that is easier to read and write than ARM templates. Bicep supports the same resources and functionality as ARM templates, but with a more intuitive syntax, better error handling, and reusable modules.

The following Bicep script creates a virtual machine in Azure:

param location string = 'eastus'
param vmName string = 'myVm'
param adminUsername string = 'admin'
param adminPassword string = 'password'

resource vm 'Microsoft.Compute/virtualMachines@2021-04-01' = {
  name: vmName
  location: location
  tags: {
    environment: 'dev'
  }
  properties: {
    hardwareProfile: {
      vmSize: 'Standard_D2_v3'
    }
    storageProfile: {
      imageReference: {
        publisher: 'MicrosoftWindowsServer'
        offer: 'WindowsServer'
        sku: '2019-Datacenter'
        version: 'latest'
      }
      osDisk: {
        createOption: 'FromImage'
      }
    }
    osProfile: {
      computerName: vmName
      adminUsername: adminUsername
      adminPassword: adminPassword
    }
    networkProfile: {
      networkInterfaces: [
        {
          id: resourceId('Microsoft.Network/networkInterfaces', '${vmName}-nic')
        }
      ]
    }
  }
}

 resource nic 'Microsoft.Network/networkInterfaces@2021-02-01' = {
  name: '${vmName}-nic'
  location: location
  properties: {
    ipConfigurations: [
      {
        name: 'ipconfig1'
        properties: {
          subnet: {
            id: resourceId('Microsoft.Network/virtualNetworks/subnets', 'myVnet', 'default')
          }
          privateIPAllocationMethod: 'Dynamic'
        }
      }
    ]
  }
}

Google Cloud Deployment Manager allows to define and manage GCP cloud infrastructures using YAML or Python templates. It is similar to Azure ARM templates. Google Cloud Deployment Manager defines and manages GCP resources, such as Compute Engine virtual machines, Google Kubernetes Engine clusters, Cloud Storage buckets, and Cloud SQL databases.

The following Cloud Deployment Manager YAML script creates a virtual machine in GCP:

resources:
- name: my-vm
  type: compute.v1.instance
  properties:
    zone: us-central1-a
    machineType: zones/us-central1-a/machineTypes/n1-standard-1
    disks:
    - deviceName: boot
      type: PERSISTENT
      boot: true
      autoDelete: true
      initializeParams:
        sourceImage: projects/debian-cloud/global/images/family/ debian-10
    networkInterfaces:
    - network: global/networks/default
      accessConfigs:
      - name: External NAT
        type: ONE_TO_ONE_NAT

AWS CloudFormation allows to define and manage AWS cloud infrastructures using JSON or YAML templates. It is similar to Azure Resource Manager (ARM) templates and Google Cloud Deployment Manager. CloudFormation can define and manage AWS resources, such as EC2 instances, S3 buckets, and RDS databases.

The following CloudFormation script creates an EC2 virtual machine in AWS:

AWSTemplateFormatVersion: '2010-09-09'
Resources:
  EC2Instance:
    Type: 'AWS::EC2::Instance'
    Properties:
      ImageId: 'ami-0c55b159cbfafe1f0' # Ubuntu 20.04 LTS
      InstanceType: 't2.micro'
      KeyName: 'my-key-pair'
      NetworkInterfaces:
        - GroupSet:
            - 'sg-0123456789abcdef' # security group
          AssociatePublicIpAddress: 'true'
          DeviceIndex: '0'
          DeleteOnTermination: 'true'

This entry was posted on Wednesday 30 April 2025

Edge computing

The goal of edge computing is to bring computing power and data storage closer to where it is needed, rather than relying on a cloud or on-premises datacenter. In edge computing, compute and storage take place on devices at the edge of the network, such as routers, gateways, switches, and sensors.

Edge computing can be a viable option where low latency, high bandwidth, and real-time processing are critical. For example, in the case of autonomous vehicles, real-time decision making is critical for safety. In this scenario, edge computing can enable the vehicle to process data and make decisions locally, rather than sending all sensor data to a centralized datacenter.

Edge computing is also gaining popularity in Internet of Things (IoT) applications, where a large number of devices generate data that must be processed in real time. By using edge computing, organizations can reduce the amount of data that needs to be sent to the cloud, which can reduce costs and improve performance.

This entry was posted on Monday 31 March 2025

Cloud computing and Infrastructure

In recent years, we have seen the widespread adoption of cloud computing. Cloud computing can be seen as one of the most important paradigm shifts in computing in recent years. Many organizations now have a cloud-first strategy and are taking steps to move applications from their own on-premises datacenters to the cloud managed by cloudproviders. 

While there are many public cloud service providers today, the three largest are Amazon Web Services (AWS), Microsoft Azure, and Google Cloud Platform (GCP). Together, these three have 66% of the market share and have a large number of datacenters around the world. The following picture shows when each of these cloud providers started. 

The three major cloud providers offer similar services, but sometimes under different names. For instance, a virtual machine in Azure is just called a virtual machine, but in GCP it is called a Compute Engine and in AWS it is called an EC2 instance.

While cloud computing can be seen as the new infrastructure, many organizations will be using on-premises infrastructure for many years to come. Migrating a complex application landscape to a cloud provider is no simple task and can take years. And maybe an organization is not allowed to take all its applications to the cloud. In many cases, there will be a hybrid situation, with part of the infrastructure on-premises and another part in one or more clouds.

Please be aware that the cloud is just a number of datacenters that are still filled with hardware – compute, networking and storage. Therefore, it is good to understand infrastructure building blocks and principles even when moving to the cloud.

Cloud definition

The most accepted definition of cloud computing is that of the National Institute of Standards and Technology (NIST)[i]:

Cloud computing is a model for enabling ubiquitous, convenient, on-demand network access to a shared pool of configurable computing resources(e.g., networks, servers, storage, applications, and services) that can be rapidly provisioned and released with minimal management effort or service provider interaction.

It is important to realize that cloud computing is not about technology; it is an outsourcing business model. It enables organizations to cut cost while at the same time focusing on their primary business – they should focus on running their business instead of running a mail server.

Clouds are composed of five essential characteristics, four deployment models, and three service models.

Cloud characteristics

Essential cloud characteristics are:

• On demand self-service – As a result of optimal automation and orchestration, minimal systems management effort is needed to deploy systems or applications in a cloud environment. In most cases, end uses can configure, deploy, start and stop systems or applications on demand.
• Rapid elasticity – A cloud is able to quickly scale-up and scale-down resources. When temporarily more processing power or storage is needed, for instance as a result of a high-exposure business marketing campaign, a cloud can scale-up very quickly on demand. When demand decreases, cloud resources can rapidly scale down, leading to elasticity of resources.
• Resource pooling – Instead of providing each application with a fixed amount of processing power and storage, cloud computing provides applications with resources from a shared pool. This is typically implemented using virtualization technologies.
• Measured service – In a cloud environment the actual resource usage is measured and billed. There are no capital expenses, only operational expenses. This in contrast with the investments needed to build a traditional infrastructure.
• Broad network access – Capabilities are available over the network and accessed through standard mechanisms.

 Be aware that when using public cloud based solutions, the internet connection becomes a Single Point of Failure. Internet availability and internet performance becomes critical and redundant connectivity is therefore key.

Cloud deployment models

A cloud can be implemented in one of four deployment models.

• A public cloud deployment is delivered by a cloud service provider, is accessible through the internet, and available to the general public. Because of their large customer base, public clouds largely benefit from economies of scale.
• A private cloud is operated solely for a single organization, whether managed internally or by a third-party, and hosted either on premises or external. It extensively uses virtualization and standardization to bring down systems management cost and staff.
• A community cloud is much like a private cloud, but shared with a community of organizations that have shared concerns (like compliance considerations). It may be owned, managed, and operated by one or more of the organizations in the community, a third party, or some combination, and it may exist on or off premises.
• In a hybrid cloud deployment, a service or application is provided by a combination of a public cloud, and a community cloud and/or a private cloud. This enables running generic services (like email servers) in the public cloud while hosting specialized services (like a business specific application) in the private or community cloud.

Cloud service models

Clouds can be delivered in one of three service models:

• Software-as-a-Service (SaaS) delivers full applications that can be used by business users, and need little or no configuration. Examples are Microsoft Office365, LinkedIn, Facebook, Twitter, and Salesforce.com.
• Platform-as-a-Service (PaaS) delivers a scalable, high available, open programming platform that can be used by developers to build bespoke applications that run on the PaaS platform. Examples are Microsoft Azure Cloud Service and Google App Engine.
• Infrastructure-as-a-Service (IaaS) delivers (virtual) machines, networking, and storage. The user needs to install and maintain the operating systems and the layers above that. Examples are Amazon Elastic Cloud (EC2 and S3) and Microsoft Azure IaaS.

The following figure shows the responsibility of the cloud provider for each service model.

In the context of infrastructure, IaaS is the most relevant service model.

When we combine both deployment and service models, we get the following picture.

The next section describes Infrastructure as s Service in more detail.

Infrastructure as a Service (IaaS)

Infrastructure as a Service provides virtual machines, virtualized storage, virtualized networking and the systems management tools to manage them. IaaS can be configured using a graphical user interface (GUI), a command line interface (CLI), or application programming interfaces (APIs).

IaaS is typically based on cheap commodity white label hardware. The philosophy is to keep the cost down by allowing the hardware to fail every now and then. Failed components are either replaced or simply removed from the pool of available resources.

IaaS provides simple, highly standardized building blocks to applications. It does not provide high availability, guaranteed performance or extensive security controls. Consequently, applications running on IaaS should be robust to allow for failing hardware and should be horizontally scalable to increase performance.

In order to use IaaS, users must create and start a new server, and then install an operating system and their applications. Since the cloud provider only provides basic services, like billing and monitoring, the user is responsible for patching and maintaining the operating systems and application software.

Not all operating systems and applications can be used in an IaaS cloud; some software licenses prohibit the use of a fully scalable, virtual environment like IaaS, where it is impossible to know in advance on which machines software will run.

This entry was posted on Friday 28 February 2025

What is IT architecture?

Most of today's infrastructure landscapes are the result of a history of application implementation projects that brought in their own specialized hardware and infrastructure components. Mergers and acquisitions have made matters worse, leaving many organizations with multiple sets of the same infrastructure services that are difficult to interconnect, let alone integrate and consolidate.

Organizations benefit from infrastructure architecture when they want to be more flexible and agile because a solid, scalable, and modular infrastructure provides a solid foundation for agile adaptations. The market demands a level of agility that can no longer be supported by infrastructures that are inconsistent and difficult to scale. We need infrastructures built with standardized, modular components. And to make infrastructures consistent and aligned with business needs, architecture is critical.

Architecture is the philosophy that underlies a system and defines its purpose, intent, and structure. Different areas of architecture can be defined, including business architecture, enterprise architecture, data architecture, application architecture, and infrastructure architecture. Each of these areas has certain unique characteristics, but at their most basic level, they all aim to map IT solutions to business value.

Architecture is needed to govern an infrastructure as it is designed, as it is used, and as it is changed. We can broadly categorize architects into three groups: enterprise architects, domain architects, and solution architects, each with their own role.

Solution architects

Solution architects create IT solutions, usually as a member of a project team. A solution architect is finished when the project is complete. Solution architects are the technical conscience and authority of a project, are responsible for architectural decisions in the project, and work closely with the project manager.

Where the project manager manages the process of a project, the solution architect manages the technical solution of the project, based on business and technical requirements.

Domain architects

Domain architects are experts on a particular business or technology topic. Because solution architects cannot always be fully knowledgeable about all technological details or specific business domain issues, domain architects often assist solution architects on projects. Domain architects also support enterprise architects because they are aware of the latest developments in their field and can inform enterprise architects about new technologies and roadmaps. Examples of domain architects are cloud architects, network architects, and VMware architects.

Domain architects most often work for infrastructure or software vendors, where they help customers implement the vendor's technologies.

Enterprise architects

Enterprise architects continuously align an organization's entire IT landscape with the business activities of the organization. Using a structured approach, enterprise architects enable transformations of the IT landscape (including the IT infrastructure). Therefore, an enterprise architect is never finished (unlike the solution architect in a project, who is finished when the project is finished).

Enterprise architects typically work closely with the CIO and business units to align the needs of the business with the current and future IT landscape. Enterprise architects build bridges and act as advisors to the business and IT.

This entry was posted on Friday 31 January 2025

Infrastructure as Code pipelines

Infra-as-code pipelines are tools that perform predefined steps to deploy infrastructure. There are many tools available for building pipelines, including Jenkins, Bamboo, AWS CodePipeline, and Azure DevOps.

As shown in the figure above a pipeline for IaC can perform the following steps to create a new infrastructure environment.

• The IaC code is stored in a version control system. Any changes made to the infrastructure code triggers the pipeline to run automatically.
• The new code is fetched from the repository.
• A test run is performed to check if the code has no errors and could be deployed in the target environment.
• After the code passes the test, it is deployed to the target environment using IaC tools.
• After all infrastructure components are created, the configuration definition is fetched from the repository.
• The configuration tool automatically configures the infrastructure components, based on the configuration definitions, leading to a running, configured infrastructure component.

Once the infrastructure is deployed, it needs to be validated to ensure that everything is working as expected.

This entry was posted on Sunday 29 December 2024