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Explore Azure App Service Azure App Service is an HTTP-based service for hosting web applications, REST APIs, and mobile back ends. You can develop in your favorite programming language or framework. Applications run and scale with ease on both Windows and Linux-based environments. Built-in auto sc...

Explore Azure App Service Azure App Service is an HTTP-based service for hosting web applications, REST APIs, and mobile back ends. You can develop in your favorite programming language or framework. Applications run and scale with ease on both Windows and Linux-based environments. Built-in auto scale support Baked into Azure App Service is the ability to scale up/down or scale out/in. Depending on the usage of the web app, you can scale the resources of the underlying machine that is hosting your web app up/down. Resources include the number of cores or the amount of RAM available. Scaling out/in is the ability to increase, or decrease, the number of machine instances that are running your web app. Continuous integration/deployment support The Azure portal provides out-of-the-box continuous integration and deployment with Azure DevOps Services, GitHub, Bitbucket, FTP, or a local Git repository on your development machine. Connect your web app with any of the above sources and App Service will do the rest for you by auto-syncing code and any future changes on the code into the web app. Deployment slots When you deploy your web app you can use a separate deployment slot instead of the default production slot when you're running in the Standard App Service Plan tier or better. Deployment slots are live apps with their own host names. App content and configurations elements can be swapped between two deployment slots, including the production slot. App Service on Linux App Service can also host web apps natively on Linux for supported application stacks. It can also run custom Linux containers (also known as Web App for Containers). App Service on Linux supports many language specific built-in images. Just deploy your code. Supported languages and frameworks include: Node.js, Java (JRE 8 & JRE 11), PHP, Python, .NET, and Ruby. If the runtime your application requires isn't supported in the built-in images, you can deploy it with a custom container. The languages, and their supported versions, are updated regularly. You can retrieve the current list by using the following command in the Cloud Shell. Bash Copy az webapp list-runtimes --os-type linux Limitations App Service on Linux does have some limitations: ● App Service on Linux isn't supported on Shared pricing tier. ● The Azure portal shows only features that currently work for Linux apps. As features are enabled, they're activated on the portal. ● When deployed to built-in images, your code and content are allocated a storage volume for web content, backed by Azure Storage. The disk latency of this volume is higher and more variable than the latency of the container filesystem. Apps that require heavy read-only access to content files may benefit from the custom container option, which places files in the container filesystem instead of on the content volume. Examine Azure App Service plans In App Service, an app always runs in an App Service plan. An App Service plan defines a set of compute resources for a web app to run. One or more apps can be configured to run on the same computing resources (or in the same App Service plan). When you create an App Service plan in a certain region (for example, West Europe), a set of compute resources is created for that plan in that region. Whatever apps you put into this App Service plan run on these compute resources as defined by your App Service plan. Each App Service plan defines: ● ● ● ● ● Operating System (Windows, Linux) Region (West US, East US, etc.) Number of VM instances Size of VM instances (Small, Medium, Large) Pricing tier (Free, Shared, Basic, Standard, Premium, PremiumV2, PremiumV3, Isolated, IsolatedV2) The pricing tier of an App Service plan determines what App Service features you get and how much you pay for the plan. There are a few categories of pricing tiers: ● Shared compute: Free and Shared, the two base tiers, runs an app on the same Azure VM as other App Service apps, including apps of other customers. These tiers allocate CPU quotas to each app that runs on the shared resources, and the resources can't scale out. ● Dedicated compute: The Basic, Standard, Premium, PremiumV2, and PremiumV3 tiers run apps on dedicated Azure VMs. Only apps in the same App Service plan share the same compute resources. The higher the tier, the more VM instances are available to you for scale-out. ● Isolated: The Isolated and IsolatedV2 tiers run dedicated Azure VMs on dedicated Azure Virtual Networks. It provides network isolation on top of compute isolation to your apps. It provides the maximum scale-out capabilities. Note App Service Free and Shared (preview) hosting plans are base tiers that run on the same Azure virtual machines as other App Service apps. Some apps might belong to other customers. These tiers are intended to be used only for development and testing purposes. How does my app run and scale? In the Free and Shared tiers, an app receives CPU minutes on a shared VM instance and can't scale out. In other tiers, an app runs and scales as follows: ● An app runs on all the VM instances configured in the App Service plan. ● If multiple apps are in the same App Service plan, they all share the same VM instances. ● If you have multiple deployment slots for an app, all deployment slots also run on the same VM instances. ● If you enable diagnostic logs, perform backups, or run WebJobs, they also use CPU cycles and memory on these VM instances. In this way, the App Service plan is the scale unit of the App Service apps. If the plan is configured to run five VM instances, then all apps in the plan run on all five instances. If the plan is configured for autoscaling, then all apps in the plan are scaled out together based on the autoscale settings. What if my app needs more capabilities or features? Your App Service plan can be scaled up and down at any time. It's as simple as changing the pricing tier of the plan. If your app is in the same App Service plan with other apps, you may want to improve the app's performance by isolating the compute resources. You can do it by moving the app into a separate App Service plan. You can potentially save money by putting multiple apps into one App Service plan. However, since apps in the same App Service plan all share the same compute resources you need to understand the capacity of the existing App Service plan and the expected load for the new app. Isolate your app into a new App Service plan when: ● The app is resource-intensive. ● You want to scale the app independently from the other apps in the existing plan. ● The app needs resource in a different geographical region. This way you can allocate a new set of resources for your app and gain greater control of your apps. Deploy to App Service Every development team has unique requirements that can make implementing an efficient deployment pipeline difficult on any cloud service. App Service supports both automated and manual deployment. Automated deployment Automated deployment, or continuous deployment, is a process used to push out new features and bug fixes in a fast and repetitive pattern with minimal effect on end users. Azure supports automated deployment directly from several sources. The following options are available: ● Azure DevOps Services: You can push your code to Azure DevOps Services, build your code in the cloud, run the tests, generate a release from the code, and finally, push your code to an Azure Web App. ● GitHub: Azure supports automated deployment directly from GitHub. When you connect your GitHub repository to Azure for automated deployment, any changes you push to your production branch on GitHub are automatically deployed for you. ● Bitbucket: With its similarities to GitHub, you can configure an automated deployment with Bitbucket. Manual deployment There are a few options that you can use to manually push your code to Azure: ● Git: App Service web apps feature a Git URL that you can add as a remote repository. Pushing to the remote repository deploys your app. ● CLI: webapp up is a feature of the az command-line interface that packages your app and deploys it. Unlike other deployment methods, az webapp up can create a new App Service web app for you if you haven't already created one. ● Zip deploy: Use curl or a similar HTTP utility to send a ZIP of your application files to App Service. ● FTP/S: FTP or FTPS is a traditional way of pushing your code to many hosting environments, including App Service. Use deployment slots Whenever possible, use deployment slots when deploying a new production build. When using a Standard App Service Plan tier or better, you can deploy your app to a staging environment and then swap your staging and production slots. The swap operation warms up the necessary worker instances to match your production scale, thus eliminating downtime. Explore authentication and authorization in App Service Azure App Service provides built-in authentication and authorization support, so you can sign in users and access data by writing minimal, or no code in your web app, RESTful API, mobile back end, and Azure Functions. Why use the built-in authentication? You're not required to use App Service for authentication and authorization. Many web frameworks are bundled with security features, and you can use them if you like. If you need more flexibility than App Service provides, you can also write your own utilities. The built-in authentication feature for App Service and Azure Functions can save you time and effort by providing out-of-the-box authentication with federated identity providers, allowing you to focus on the rest of your application. ● Azure App Service allows you to integrate various auth capabilities into your web app or API without implementing them yourself. ● It’s built directly into the platform and doesn’t require any particular language, SDK, security expertise, or code. ● You can integrate with multiple login providers. For example, Microsoft Entra ID, Facebook, Google, Twitter. Identity providers App Service uses federated identity, in which a third-party identity provider manages the user identities and authentication flow for you. The following identity providers are available by default: Provider Sign-in endpoint How-To guidance Microsoft identity /.auth/login/aad App Service Microsoft identity platform Facebook platform login /.auth/login/facebook App Service Facebook login Google /.auth/login/google App Service Google login Twitter /.auth/login/twitter App Service Twitter login Any OpenID Connect /.auth/login/<providerN App Service OpenID Connect provider ame> /.auth/login/github GitHub login App Service GitHub login When you enable authentication and authorization with one of these providers, its sign-in endpoint is available for user authentication and for validation of authentication tokens from the provider. You can provide your users with any number of these sign-in options. How it works The authentication and authorization module runs in the same sandbox as your application code. When it's enabled, every incoming HTTP request passes through it before being handled by your application code. This module handles several things for your app: ● Authenticates users and clients with the specified identity provider(s) ● Validates, stores, and refreshes OAuth tokens issued by the configured identity provider(s) ● Manages the authenticated session ● Injects identity information into HTTP request headers The module runs separately from your application code and can be configured using Azure Resource Manager settings or using a configuration file. No SDKs, specific programming languages, or changes to your application code are required. Note In Linux and containers the authentication and authorization module runs in a separate container, isolated from your application code. Because it does not run in-process, no direct integration with specific language frameworks is possible. Authentication flow The authentication flow is the same for all providers, but differs depending on whether you want to sign in with the provider's SDK. ● Without provider SDK: The application delegates federated sign-in to App Service. This is typically the case with browser apps, which can present the provider's login page to the user. The server code manages the sign-in process, so it's also called server-directed flow or server flow. ● With provider SDK: The application signs users in to the provider manually and then submits the authentication token to App Service for validation. This is typically the case with browser-less apps, which can't present the provider's sign-in page to the user. The application code manages the sign-in process, so it's also called client-directed flow or client flow. This applies to REST APIs, Azure Functions, JavaScript browser clients, and native mobile apps that sign users in using the provider's SDK. The following table shows the steps of the authentication flow. Step Without provider SDK With provider SDK Sign user in Redirects client to Client code signs user in directly /.auth/login/<provider>. with provider's SDK and receives an authentication token. For information, see the provider's documentation. Post-authent Provider redirects client to Client code posts token from ication /.auth/login/<provider>/callbac provider to k. /.auth/login/<provider> for validation. Establish App Service adds authenticated App Service returns its own authenticate cookie to response. authentication token to client d session code. Serve Client includes authentication Client code presents authenticate cookie in subsequent requests authentication token in d content (automatically handled by X-ZUMO-AUTH browser). header (automatically handled by Mobile Apps client SDKs). For client browsers, App Service can automatically direct all unauthenticated users to /.auth/login/<provider>. You can also present users with one or more /.auth/login/<provider> links to sign in to your app using their provider of choice. Authorization behavior In the Azure portal, you can configure App Service with many behaviors when an incoming request isn't authenticated. ● Allow unauthenticated requests: This option defers authorization of unauthenticated traffic to your application code. For authenticated requests, App Service also passes along authentication information in the HTTP headers. This option provides more flexibility in handling anonymous requests. It lets you present multiple sign-in providers to your users. ● Require authentication: This option rejects any unauthenticated traffic to your application. This rejection can be a redirect action to one of the configured identity providers. In these cases, a browser client is redirected to /.auth/login/<provider> for the provider you choose. If the anonymous request comes from a native mobile app, the returned response is an HTTP 401 Unauthorized. You can also configure the rejection to be an HTTP 401 Unauthorized or HTTP 403 Forbidden for all requests. Caution Restricting access in this way applies to all calls to your app, which may not be desirable for apps wanting a publicly available home page, as in many single-page applications. Token store App Service provides a built-in token store, which is a repository of tokens that are associated with the users of your web apps, APIs, or native mobile apps. When you enable authentication with any provider, this token store is immediately available to your app. Logging and tracing If you enable application logging, authentication and authorization traces are collected directly in your log files. If you see an authentication error that you didn't expect, you can conveniently find all the details by looking in your existing application logs. Discover App Service networking features By default, apps hosted in App Service are accessible directly through the internet and can reach only internet-hosted endpoints. But for many applications, you need to control the inbound and outbound network traffic. There are two main deployment types for Azure App Service. The multitenant public service hosts App Service plans in the Free, Shared, Basic, Standard, Premium, PremiumV2, and PremiumV3 pricing SKUs. There's also the single-tenant App Service Environment (ASE) hosts Isolated SKU App Service plans directly in your Azure virtual network. Multi-tenant App Service networking features Azure App Service is a distributed system. The roles that handle incoming HTTP or HTTPS requests are called front ends. The roles that host the customer workload are called workers. All the roles in an App Service deployment exist in a multi-tenant network. Because there are many different customers in the same App Service scale unit, you can't connect the App Service network directly to your network. Instead of connecting the networks, you need features to handle the various aspects of application communication. The features that handle requests to your app can't be used to solve problems when you're making calls from your app. Likewise, the features that solve problems for calls from your app can't be used to solve problems to your app. Inbound features Outbound features App-assigned address Hybrid Connections Access restrictions Gateway-required virtual network integration Service endpoints Virtual network integration Private endpoints You can mix the features to solve your problems with a few exceptions. The following inbound use cases are examples of how to use App Service networking features to control traffic inbound to your app. Inbound use case Feature Support IP-based SSL needs for your app App-assigned address Support unshared dedicated inbound address for your App-assigned address app Restrict access to your app from a set of well-defined Access restrictions addresses Default networking behavior Azure App Service scale units support many customers in each deployment. The Free and Shared SKU plans host customer workloads on multitenant workers. The Basic and higher plans host customer workloads that are dedicated to only one App Service plan. If you have a Standard App Service plan, all the apps in that plan run on the same worker. If you scale out the worker, all the apps in that App Service plan are replicated on a new worker for each instance in your App Service plan. Outbound addresses The worker VMs are broken down in large part by the App Service plans. The Free, Shared, Basic, Standard, and Premium plans all use the same worker VM type. The PremiumV2 plan uses another VM type. PremiumV3 uses yet another VM type. When you change the VM family, you get a different set of outbound addresses. There are many addresses that are used for outbound calls. The outbound addresses used by your app for making outbound calls are listed in the properties for your app. These addresses are shared by all the apps running on the same worker VM family in the App Service deployment. If you want to see all the addresses that your app might use in a scale unit, there's a property called possibleOutboundIpAddresses that lists them. Find outbound IPs To find the outbound IP addresses currently used by your app in the Azure portal, select Properties in your app's left-hand navigation. You can find the same information by running the following Azure CLI command in the Cloud Shell. They're listed in the Additional Outbound IP Addresses field. Bash Copy az webapp show \ --resource-group <group_name> \ --name <app_name> \ --query outboundIpAddresses \ --output tsv To find all possible outbound IP addresses for your app, regardless of pricing tiers, run the following command in the Cloud Shell. Bash Copy az webapp show \ --resource-group <group_name> \ --name <app_name> \ --query possibleOutboundIpAddresses \ --output tsv

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