Container Apps Azapi Terraform Save
This sample shows how to deploy a Dapr application to Azure Container Apps using Terraform with the AzAPI Provider.
page_type: sample languages:
- azurecli
- bash
- terraform
- yaml
- json products:
- azure
- azure-container-apps
- azure-storage
- azure-blob-storage
- azure-storage-accounts
- azure-monitor
- azure-log-analytics
- azure-application-insights
name: Deploy a Dapr application to Azure Container Apps with Terraform description: This sample shows how to deploy a Dapr application to Azure Container Apps using Terraform modules and the AzAPI Provider. urlFragment: container-apps-azapi-terraform
Deploy a Dapr application to Azure Container Apps with Terraform
Dapr (Distributed Application Runtime) is a runtime that helps you build resilient stateless and stateful microservices. This sample shows how to deploy a Dapr application to Azure Container Apps using Terraform modules with the Azure Provider and AzAPI Provider Terraform Providers instead of an Azure Resource Manager (ARM) or Bicep template like in the original sample Tutorial: Deploy a Dapr application to Azure Container Apps with an Azure Resource Manager or Bicep template.
In this sample you will learn how to:
- Use the following resources from the Azure Provider:
- Use Terraform and AzAPI Provider to deploy or update an Azure resource using the following data sources and resources
- resources:
- data sources:
- Create an Azure Blob Storage for use as a Dapr state store
- Deploy an Azure Container Apps environment to host one or more Azure Container Apps
- Deploy two Dapr-enabled Azure Container Apps: one that produces orders and one that consumes orders and stores them
- Verify the interaction between the two microservices.
With Azure Container Apps, you get a fully managed version of the Dapr APIs when building microservices. When you use Dapr in Azure Container Apps, you can enable sidecars to run next to your microservices that provide a rich set of capabilities. Available Dapr APIs include Service to Service calls, Pub/Sub, Event Bindings, State Stores, and Actors.
In this sample, you deploy the same applications from the Dapr Hello World quickstart.
The application consists of:
- A client (Python) container app to generate messages.
- A service (Node) container app to consume and persist those messages in a state store
The following architecture diagram illustrates the components that make up this tutorial:
Prerequisites
- Install Azure CLI
- An Azure account with an active subscription is required. If you don't already have one, you can create an account for free. If you don't have one, create a free Azure account before you begin.
- Visual Studio Code installed on one of the supported platforms along with the HashiCorp Terraform.>
Terraform Providers
The Azure Provider can be used to configure infrastructure in Microsoft Azure using the Azure Resource Manager API's. For more information on the data sources and resources supported by the Azure Provider, see the documentation. To learn the basics of Terraform using this provider, follow the hands-on get started tutorials. If you are interested in the Azure Provider's latest features, see the changelog for version information and release notes.
The AzAPI Provider is a very thin layer on top of the Azure ARM REST APIs. This provider compliments the AzureRM provider by enabling the management of Azure resources that are not yet or may never be supported in the AzureRM provider such as private/public preview services and features. The AzAPI provider enables you to manage any Azure resource type using any API version. This provider complements the AzureRM provider by enabling the management of new Azure resources and properties (including private preview). For more information, see Overview of the Terraform AzAPI provider.
Terraform modules
This sample contains Terraform modules to create the following resources:
- Microsoft.OperationalInsights/workspaces: an Azure Log Analytics workspace used to collect logs and metrics of the Azure Container Apps environment.
- Microsoft.Insights/components: an Azure Application Insights used by the Azure Container Apps for logging and distributed tracing.
- Microsoft.Storage/storageAccounts: this storage account is used to store state of the Dapr component.
- Microsoft.App/managedEnvironments: an Azure Container Apps environment that will host two Azure Container Apps.
- Microsoft.App/managedEnvironments/daprComponents: a state management Dapr component that hosts the orders created by the service application.
- Microsoft.App/containerApps: two dapr-enabled Container Apps: hello-k8s-node and hello-k8s-python
The following table contains the code of the modules/contains_apps/main.tf Terraform module used to create the Azure Container Apps environment, Dapr components, and Container Apps.
terraform {
required_version = ">= 1.3"
required_providers {
azurerm = {
source = "hashicorp/azurerm"
version = "~> 3.43.0"
}
azapi = {
source = "azure/azapi"
}
}
}
resource "azurerm_container_app_environment" "managed_environment" {
name = var.managed_environment_name
location = var.location
resource_group_name = var.resource_group_name
log_analytics_workspace_id = var.workspace_id
infrastructure_subnet_id = var.infrastructure_subnet_id
internal_load_balancer_enabled = var.internal_load_balancer_enabled
tags = var.tags
lifecycle {
ignore_changes = [
tags
]
}
}
resource "azurerm_container_app_environment_dapr_component" "dapr_component" {
for_each = {for component in var.dapr_components: component.name => component}
name = each.key
container_app_environment_id = azurerm_container_app_environment.managed_environment.id
component_type = each.value.component_type
version = each.value.version
ignore_errors = each.value.ignore_errors
init_timeout = each.value.init_timeout
scopes = each.value.scopes
dynamic "metadata" {
for_each = each.value.metadata != null ? each.value.metadata : []
content {
name = metadata.value.name
secret_name = try(metadata.value.secret_name, null)
value = try(metadata.value.value, null)
}
}
dynamic "secret" {
for_each = each.value.secret != null ? each.value.secret : []
content {
name = secret.value.name
value = secret.value.value
}
}
}
resource "azurerm_container_app" "container_app" {
for_each = {for app in var.container_apps: app.name => app}
name = each.key
resource_group_name = var.resource_group_name
container_app_environment_id = azurerm_container_app_environment.managed_environment.id
tags = var.tags
revision_mode = each.value.revision_mode
template {
dynamic "container" {
for_each = coalesce(each.value.template.containers, [])
content {
name = container.value.name
image = container.value.image
args = try(container.value.args, null)
command = try(container.value.command, null)
cpu = container.value.cpu
memory = container.value.memory
dynamic "env" {
for_each = coalesce(container.value.env, [])
content {
name = env.value.name
secret_name = try(env.value.secret_name, null)
value = try(env.value.value, null)
}
}
}
}
min_replicas = try(each.value.template.min_replicas, null)
max_replicas = try(each.value.template.max_replicas, null)
revision_suffix = try(each.value.template.revision_suffix, null)
dynamic "volume" {
for_each = each.value.template.volume != null ? [each.value.template.volume] : []
content {
name = volume.value.name
storage_name = try(volume.value.storage_name, null)
storage_type = try(volume.value.storage_type, null)
}
}
}
dynamic "ingress" {
for_each = each.value.ingress != null ? [each.value.ingress] : []
content {
allow_insecure_connections = try(ingress.value.allow_insecure_connections, null)
external_enabled = try(ingress.value.external_enabled, null)
target_port = ingress.value.target_port
transport = ingress.value.transport
dynamic "traffic_weight" {
for_each = coalesce(ingress.value.traffic_weight, [])
content {
label = traffic_weight.value.label
latest_revision = traffic_weight.value.latest_revision
revision_suffix = traffic_weight.value.revision_suffix
percentage = traffic_weight.value.percentage
}
}
}
}
dynamic "dapr" {
for_each = each.value.dapr != null ? [each.value.dapr] : []
content {
app_id = dapr.value.app_id
app_port = dapr.value.app_port
app_protocol = dapr.value.app_protocol
}
}
dynamic "secret" {
for_each = each.value.secrets != null ? [each.value.secrets] : []
content {
name = secret.value.name
value = secret.value.value
}
}
lifecycle {
ignore_changes = [
tags
]
}
}
resource "azapi_update_resource" "containerapp" {
type = "Microsoft.App/containerApps@2022-10-01"
resource_id = azurerm_container_app.container_app["pythonapp"].id
body = jsonencode({
properties = {
configuration = {
dapr = {
appPort = null
}
}
}
})
depends_on = [
azurerm_container_app.container_app["pythonapp"],
]
}
As you can see, the module uses the following resources of the Azure Provider:
- azurerm_container_app_environment: this resource is used to create the Azure Container Apps environment which acts as a secure boundary around the container apps. Container Apps in the same environment are deployed in the same virtual network and write logs to the same Log Analytics workspace.
-
azurerm_container_app_environment_dapr_component: the Distributed Application Runtime ([Dapr][dapr-concepts]) is a set of incrementally adoptable features that simplify the authoring of distributed, microservice-based applications. For example, Dapr provides capabilities for enabling application intercommunication, whether through messaging via pub/sub or reliable and secure service-to-service calls. Once Dapr is enabled for a container app, a secondary process will be created alongside your application code that will enable communication with Dapr via HTTP or gRPC. This component is used to deploy a collection of Dapr components defined in the
dapr_componentsvariable. This sample deploys a single State Management Dapr component that uses an Azure Blob Storage as a state store. -
azurerm_container_app: this resource is used to deploy a configurable collection of Azure Container Apps in the Azure Container Apps environment. The container apps are defined in the
container_appsvariable.
When the Azure Provider does not provide the necessary data sources and resources to create Azure resources or the existing data sources and resources do not yet expose a block or property, you can use the data sources and resources of the AzAPI Provider to create or modify Azure resources.
At the time of this writing, the app_port property under the dapr block in the azurerm_container_app resource is defined as required. You should be able to set the value of this property to null to create headless applications, like the pythonapp in this tutorial, with no ingress, hence, with no app_port. I submitted a pull request to turn the the app_port property under the dapr block in the azurerm_container_app resource from required to optional. While waiting for the pull request to be accepted, as a temporary solution we can use an azapi_update_resource resource of the AzAPI Provider to set the appPort of the pythonapp container app to null after creating the resource with the azurerm_container_app of the Azure Provider.
AzAPI Provider
The azapi folder of the companion project contains an old version of the sample where the Container App environment, Container Apps, and Dapr component used by the sample are all deployed using azapi_resource resources of the AzAPI Provider. Below you can see the code of the azapi/modules/container_apps/main.tfmodule.
terraform {
required_version = ">= 1.3"
required_providers {
azurerm = {
source = "hashicorp/azurerm"
version = "~> 3.43.0"
}
azapi = {
source = "Azure/azapi"
}
}
experiments = [module_variable_optional_attrs]
}
locals {
module_tag = {
"module" = basename(abspath(path.module))
}
tags = merge(var.tags, local.module_tag)
}
resource "azapi_resource" "managed_environment" {
name = var.managed_environment_name
location = var.location
parent_id = var.resource_group_id
type = "Microsoft.App/managedEnvironments@2022-03-01"
tags = local.tags
body = jsonencode({
properties = {
daprAIInstrumentationKey = var.instrumentation_key
appLogsConfiguration = {
destination = "log-analytics"
logAnalyticsConfiguration = {
customerId = var.workspace_id
sharedKey = var.primary_shared_key
}
}
}
})
lifecycle {
ignore_changes = [
tags
]
}
}
resource "azapi_resource" "daprComponents" {
for_each = {for component in var.dapr_components: component.name => component}
name = each.key
parent_id = azapi_resource.managed_environment.id
type = "Microsoft.App/managedEnvironments/daprComponents@2022-03-01"
body = jsonencode({
properties = {
componentType = each.value.componentType
version = each.value.version
ignoreErrors = each.value.ignoreErrors
initTimeout = each.value.initTimeout
secrets = each.value.secrets
metadata = each.value.metadata
scopes = each.value.scopes
}
})
}
resource "azapi_resource" "container_app" {
for_each = {for app in var.container_apps: app.name => app}
name = each.key
location = var.location
parent_id = var.resource_group_id
type = "Microsoft.App/containerApps@2022-03-01"
tags = local.tags
body = jsonencode({
properties: {
managedEnvironmentId = azapi_resource.managed_environment.id
configuration = {
ingress = try(each.value.configuration.ingress, null)
dapr = try(each.value.configuration.dapr, null)
}
template = each.value.template
}
})
lifecycle {
ignore_changes = [
tags
]
}
}
You can use an azapi_resource resource to create any Azure resource. For more information, see Overview of the Terraform AzAPI provider.
Deploy the sample
All the resources deployed by the modules share the same name prefix. Make sure to configure a name prefix by setting a value for the resource_prefix variable defined in the variables.tf file. If you set the value of the resource_prefix variable to an empty string, the main.tf module will use a random_string resource to automatically create a name prefix for the Azure resources. You can use the deploy.sh bash script to deploy the sample:
#!/bin/bash
# Terraform Init
terraform init
# Terraform validate
terraform validate -compact-warnings
# Terraform plan
terraform plan -compact-warnings -out main.tfplan
# Terraform apply
terraform apply -compact-warnings -auto-approve main.tfplan
This command deploys the Terraform modules that create the following resources:
- The Container Apps environment and associated Log Analytics workspace for hosting the hello world Dapr solution.
- An Application Insights instance for Dapr distributed tracing.
- The
nodeappapp server running ontargetPort: 3000with dapr enabled and configured using:"appId": "nodeapp"and"appPort": 3000. - The
daprComponentsobject of"type": "state.azure.blobstorage"scoped for use by thenodeappfor storing state. - The headless
pythonappwith no ingress and Dapr enabled that calls thenodeappservice via dapr service-to-service communication.
Verify the result
Confirm successful state persistence
You can confirm that the services are working correctly by viewing data in your Azure Storage account.
- Open the Azure portal in your browser.
- Navigate to your storage account.
- Select Containers from the menu on the left side.
- Select state.
- Verify that you can see the file named
orderin the container. - Select on the file.
- Select the Edit tab.
- Select the Refresh button to observe updates.
View Logs
Data logged via a container app are stored in the ContainerAppConsoleLogs_CL custom table in the Log Analytics workspace. You can view logs through the Azure portal or from the command line. Wait a few minutes for the analytics to arrive for the first time before you query the logged data.
- Open the Azure portal in your browser.
- Navigate to your log analytics workspace.
- Select Logs from the menu on the left side.
- Run the following Kusto query.
ContainerAppConsoleLogs_CL
| project TimeGenerated, ContainerAppName_s, Log_s
| order by TimeGenerated desc
The following images shows the type of response to expect from the command.
Clean up resources
Once you are done, run the following command to delete your resource group along with all the resources you created in this tutorial.
az group delete \
--resource-group $RESOURCE_GROUP
Since pythonapp continuously makes calls to nodeapp with messages that get persisted into your configured state store, it is important to complete these cleanup steps to avoid ongoing billable operations.
Next steps
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