Azure.Messaging.ServiceBus 7.18.1

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dotnet add package Azure.Messaging.ServiceBus --version 7.18.1                
NuGet\Install-Package Azure.Messaging.ServiceBus -Version 7.18.1                
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<PackageReference Include="Azure.Messaging.ServiceBus" Version="7.18.1" />                
For projects that support PackageReference, copy this XML node into the project file to reference the package.
paket add Azure.Messaging.ServiceBus --version 7.18.1                
#r "nuget: Azure.Messaging.ServiceBus, 7.18.1"                
#r directive can be used in F# Interactive and Polyglot Notebooks. Copy this into the interactive tool or source code of the script to reference the package.
// Install Azure.Messaging.ServiceBus as a Cake Addin
#addin nuget:?package=Azure.Messaging.ServiceBus&version=7.18.1

// Install Azure.Messaging.ServiceBus as a Cake Tool
#tool nuget:?package=Azure.Messaging.ServiceBus&version=7.18.1                

Azure Service Bus client library for .NET

Azure Service Bus allows you to build applications that take advantage of asynchronous messaging patterns using a highly-reliable service to broker messages between producers and consumers. Azure Service Bus provides flexible, brokered messaging between client and server, along with structured first-in, first-out (FIFO) messaging, and publish/subscribe capabilities with complex routing. If you would like to know more about Azure Service Bus, you may wish to review: What is Azure Service Bus?

Use the client library for Azure Service Bus to:

  • Transfer business data: leverage messaging for durable exchange of information, such as sales or purchase orders, journals, or inventory movements.

  • Decouple applications: improve reliability and scalability of applications and services, relieving senders and receivers of the need to be online at the same time.

  • Control how messages are processed: support traditional competing consumers for messages using queues or allow each consumer their own instance of a message using topics and subscriptions.

  • Implement complex workflows: message sessions support scenarios that require message ordering or message deferral.

Source code | Package (NuGet) | API reference documentation | Product documentation | Migration guide (Microsoft.Azure.ServiceBus) | Migration guide (WindowsAzure.ServiceBus) | Troubleshooting guide

Getting started

Prerequisites

  • Microsoft Azure Subscription: To use Azure services, including Azure Service Bus, you'll need a subscription. If you do not have an existing Azure account, you may sign up for a free trial or use your MSDN subscriber benefits when you create an account.

  • Service Bus namespace: To interact with Azure Service Bus, you'll also need to have a namespace available. If you are not familiar with creating Azure resources, you may wish to follow the step-by-step guide for creating a Service Bus namespace using the Azure portal. There, you can also find detailed instructions for using the Azure CLI, Azure PowerShell, or Azure Resource Manager (ARM) templates to create a Service bus entity.

  • C# 8.0: The Azure Service Bus client library makes use of new features that were introduced in C# 8.0. In order to take advantage of the C# 8.0 syntax, it is recommended that you compile using the .NET Core SDK 3.0 or higher with a language version of latest.

    Visual Studio users wishing to take full advantage of the C# 8.0 syntax will need to use Visual Studio 2019 or later. Visual Studio 2019, including the free Community edition, can be downloaded here. Users of Visual Studio 2017 can take advantage of the C# 8 syntax by making use of the Microsoft.Net.Compilers NuGet package and setting the language version, though the editing experience may not be ideal.

    You can still use the library with previous C# language versions, but will need to manage asynchronous enumerable and asynchronous disposable members manually rather than benefiting from the new syntax. You may still target any framework version supported by your .NET Core SDK, including earlier versions of .NET Core or the .NET framework. For more information, see: how to specify target frameworks.

    Important Note: In order to build or run the examples and the samples without modification, use of C# 8.0 is mandatory. You can still run the samples if you decide to tweak them for other language versions.

To quickly create the needed Service Bus resources in Azure and to receive a connection string for them, you can deploy our sample template by clicking:

Deploy to Azure

Install the package

Install the Azure Service Bus client library for .NET with NuGet:

dotnet add package Azure.Messaging.ServiceBus

Authenticate the client

For the Service Bus client library to interact with a queue or topic, it will need to understand how to connect and authorize with it. The easiest means for doing so is to use a connection string, which is created automatically when creating a Service Bus namespace. If you aren't familiar with shared access policies in Azure, you may wish to follow the step-by-step guide to get a Service Bus connection string.

Once you have a connection string, you can authenticate your client with it.

// Create a ServiceBusClient that will authenticate using a connection string
string connectionString = "<connection_string>";
await using var client = new ServiceBusClient(connectionString);

To see how to authenticate using Azure.Identity, view this example.

For examples of how to authenticate for an ASP.NET Core application, view this example.

To see how to initiate the connection with a custom endpoint, view this sample.

Key concepts

Once you've initialized a ServiceBusClient, you can interact with the primary resource types within a Service Bus Namespace, of which multiple can exist and on which actual message transmission takes place, the namespace often serving as an application container:

  • Queue: Allows for Sending and Receiving of messages. Often used for point-to-point communication.

  • Topic: As opposed to Queues, Topics are better suited to publish/subscribe scenarios. A topic can be sent to, but requires a subscription, of which there can be multiple in parallel, to consume from.

  • Subscription: The mechanism to consume from a Topic. Each subscription is independent, and receives a copy of each message sent to the topic. Rules and Filters can be used to tailor which messages are received by a specific subscription.

For more information about these resources, see What is Azure Service Bus?.

To interact with these resources, one should be familiar with the following SDK concepts:

  • A Service Bus client is the primary interface for developers interacting with the Service Bus client library. It serves as the gateway from which all interaction with the library will occur.

  • A Service Bus sender is scoped to a particular queue or topic, and is created using the Service Bus client. The sender allows you to send messages to a queue or topic. It also allows for scheduling messages to be available for delivery at a specified date.

  • A Service Bus receiver is scoped to a particular queue or subscription, and is created using the Service Bus client. The receiver allows you to receive messages from a queue or subscription. It also allows the messages to be settled after receiving them. There are four ways of settling messages:

    • Complete - causes the message to be deleted from the queue or topic.
    • Abandon - releases the receiver's lock on the message allowing for the message to be received by other receivers.
    • Defer - defers the message from being received by normal means. In order to receive deferred messages, the sequence number of the message needs to be retained.
    • DeadLetter - moves the message to the Dead Letter queue. This will prevent the message from being received again. In order to receive messages from the Dead Letter queue, a receiver scoped to the Dead Letter queue is needed.
  • A Service Bus session receiver is scoped to a particular session-enabled queue or subscription, and is created using the Service Bus client. The session receiver is almost identical to the standard receiver, with the difference being that session management operations are exposed which only apply to session-enabled entities. These operations include getting and setting session state, as well as renewing session locks.

  • A Service Bus processor is scoped to a particular queue or subscription, and is created using the Service Bus client. The ServiceBusProcessor can be thought of as an abstraction around a set of receivers. It uses a callback model to allow code to be specified when a message is received and when an exception occurs. It offers automatic completion of processed messages, automatic message lock renewal, and concurrent execution of user specified event handlers. Because of its feature set, it should be the go to tool for writing applications that receive from Service Bus entities. The ServiceBusReceiver is recommended for more complex scenarios in which the processor is not able to provide the fine-grained control that one can expect when using the ServiceBusReceiver directly.

  • A Service Bus session processor is scoped to a particular session-enabled queue or subscription, and is created using the Service Bus client. The session processor is almost identical to the standard processor, with the difference being that session management operations are exposed which only apply to session-enabled entities.

For more concepts and deeper discussion, see: Service Bus Advanced Features.

Client lifetime

The ServiceBusClient, senders, receivers, and processors are safe to cache and use as a singleton for the lifetime of the application, which is best practice when messages are being sent or received regularly. They are responsible for efficient management of network, CPU, and memory use, working to keep usage low during periods of inactivity.

These types are disposable and calling either DisposeAsync or CloseAsync is required to ensure that network resources and other unmanaged objects are properly cleaned up. It is important to note that when a ServiceBusClient instance is disposed, the underlying AMQP connection is closed, therefore any senders, receivers, and processors that were created using it can no longer be used, whether or not the senders, receivers, and processors were explicitly closed. The best practice is to close the senders, receivers, and processors to ensure cleanup of the AMQP links, and then to close the ServiceBusClient to ensure the AMQP connection is closed.

Thread safety

We guarantee that all client instance methods are thread-safe and independent of each other (guideline). This ensures that the recommendation of reusing client instances is always safe, even across threads.

Additional concepts

Client options | Diagnostics | Mocking

Examples

Send and receive a message

Message sending is performed using the ServiceBusSender. Receiving is performed using the ServiceBusReceiver.

string connectionString = "<connection_string>";
string queueName = "<queue_name>";
// since ServiceBusClient implements IAsyncDisposable we create it with "await using"
await using var client = new ServiceBusClient(connectionString);

// create the sender
ServiceBusSender sender = client.CreateSender(queueName);

// create a message that we can send. UTF-8 encoding is used when providing a string.
ServiceBusMessage message = new ServiceBusMessage("Hello world!");

// send the message
await sender.SendMessageAsync(message);

// create a receiver that we can use to receive the message
ServiceBusReceiver receiver = client.CreateReceiver(queueName);

// the received message is a different type as it contains some service set properties
ServiceBusReceivedMessage receivedMessage = await receiver.ReceiveMessageAsync();

// get the message body as a string
string body = receivedMessage.Body.ToString();
Console.WriteLine(body);

Sending a batch of messages

There are two ways of sending several messages at once. The first way of doing this uses safe-batching. With safe-batching, you can create a ServiceBusMessageBatch object, which will allow you to attempt to add messages one at a time to the batch using the TryAdd method. If the message cannot fit in the batch, TryAdd will return false.

// add the messages that we plan to send to a local queue
Queue<ServiceBusMessage> messages = new Queue<ServiceBusMessage>();
messages.Enqueue(new ServiceBusMessage("First message"));
messages.Enqueue(new ServiceBusMessage("Second message"));
messages.Enqueue(new ServiceBusMessage("Third message"));

// create a message batch that we can send
// total number of messages to be sent to the Service Bus queue
int messageCount = messages.Count;

// while all messages are not sent to the Service Bus queue
while (messages.Count > 0)
{
    // start a new batch
    using ServiceBusMessageBatch messageBatch = await sender.CreateMessageBatchAsync();

    // add the first message to the batch
    if (messageBatch.TryAddMessage(messages.Peek()))
    {
        // dequeue the message from the .NET queue once the message is added to the batch
        messages.Dequeue();
    }
    else
    {
        // if the first message can't fit, then it is too large for the batch
        throw new Exception($"Message {messageCount - messages.Count} is too large and cannot be sent.");
    }

    // add as many messages as possible to the current batch
    while (messages.Count > 0 && messageBatch.TryAddMessage(messages.Peek()))
    {
        // dequeue the message from the .NET queue as it has been added to the batch
        messages.Dequeue();
    }

    // now, send the batch
    await sender.SendMessagesAsync(messageBatch);

    // if there are any remaining messages in the .NET queue, the while loop repeats
}

The second way uses the SendMessagesAsync overload that accepts an IEnumerable of ServiceBusMessage. With this method, we will attempt to fit all of the supplied messages in a single message batch that we will send to the service. If the messages are too large to fit in a single batch, the operation will throw an exception.

IList<ServiceBusMessage> messages = new List<ServiceBusMessage>();
messages.Add(new ServiceBusMessage("First"));
messages.Add(new ServiceBusMessage("Second"));
// send the messages
await sender.SendMessagesAsync(messages);

Receiving a batch of messages

// create a receiver that we can use to receive the messages
ServiceBusReceiver receiver = client.CreateReceiver(queueName);

// the received message is a different type as it contains some service set properties
// a batch of messages (maximum of 2 in this case) are received
IReadOnlyList<ServiceBusReceivedMessage> receivedMessages = await receiver.ReceiveMessagesAsync(maxMessages: 2);

// go through each of the messages received
foreach (ServiceBusReceivedMessage receivedMessage in receivedMessages)
{
    // get the message body as a string
    string body = receivedMessage.Body.ToString();
}

Complete a message

In order to remove a message from a queue or subscription, we can call the CompleteMessageAsync method.

string connectionString = "<connection_string>";
string queueName = "<queue_name>";
// since ServiceBusClient implements IAsyncDisposable we create it with "await using"
await using var client = new ServiceBusClient(connectionString);

// create the sender
ServiceBusSender sender = client.CreateSender(queueName);

// create a message that we can send
ServiceBusMessage message = new ServiceBusMessage("Hello world!");

// send the message
await sender.SendMessageAsync(message);

// create a receiver that we can use to receive and settle the message
ServiceBusReceiver receiver = client.CreateReceiver(queueName);

// the received message is a different type as it contains some service set properties
ServiceBusReceivedMessage receivedMessage = await receiver.ReceiveMessageAsync();

// complete the message, thereby deleting it from the service
await receiver.CompleteMessageAsync(receivedMessage);

Abandon a message

Abandoning a message releases our receiver's lock, which allows the message to be received by this or other receivers.

ServiceBusReceivedMessage receivedMessage = await receiver.ReceiveMessageAsync();

// abandon the message, thereby releasing the lock and allowing it to be received again by this or other receivers
await receiver.AbandonMessageAsync(receivedMessage);

Defer a message

Deferring a message will prevent it from being received again using the ReceiveMessageAsync or ReceiveMessagesAsync methods. Instead, there are separate methods, ReceiveDeferredMessageAsync and ReceiveDeferredMessagesAsync for receiving deferred messages.

ServiceBusReceivedMessage receivedMessage = await receiver.ReceiveMessageAsync();

// defer the message, thereby preventing the message from being received again without using
// the received deferred message API.
await receiver.DeferMessageAsync(receivedMessage);

// receive the deferred message by specifying the service set sequence number of the original
// received message
ServiceBusReceivedMessage deferredMessage = await receiver.ReceiveDeferredMessageAsync(receivedMessage.SequenceNumber);

Dead letter a message

Dead lettering a message is similar to deferring with one main difference being that messages will be automatically dead lettered by the service after they have been received a certain number of times. Applications can choose to manually dead letter messages based on their requirements. When a message is dead lettered it is actually moved to a subqueue of the original queue. Note that the ServiceBusReceiver is used to receive messages from the dead letter subqueue regardless of whether or not the main queue is session-enabled.

ServiceBusReceivedMessage receivedMessage = await receiver.ReceiveMessageAsync();

// Dead-letter the message, thereby preventing the message from being received again without receiving from the dead letter queue.
// We can optionally pass a dead letter reason and dead letter description to further describe the reason for dead-lettering the message.
await receiver.DeadLetterMessageAsync(receivedMessage, "sample reason", "sample description");

// receive the dead lettered message with receiver scoped to the dead letter queue.
ServiceBusReceiver dlqReceiver = client.CreateReceiver(queueName, new ServiceBusReceiverOptions
{
    SubQueue = SubQueue.DeadLetter
});
ServiceBusReceivedMessage dlqMessage = await dlqReceiver.ReceiveMessageAsync();

// The reason and the description that we specified when dead-lettering the message will be available in the received dead letter message.
string reason = dlqMessage.DeadLetterReason;
string description = dlqMessage.DeadLetterErrorDescription;

For more information, see the overview of ServiceBus dead letter queues.

Using the Processor

The ServiceBusProcessor can be thought of as an abstraction around a set of receivers. It uses a callback model to allow code to be specified when a message is received and when an exception occurs. It offers automatic completion of processed messages, automatic message lock renewal, and concurrent execution of user specified event handlers. Because of its feature set, it should be the go to tool for writing applications that receive from Service Bus entities. The ServiceBusReceiver is recommended for more complex scenarios in which the processor is not able to provide the fine-grained control that one can expect when using the ServiceBusReceiver directly.

string connectionString = "<connection_string>";
string queueName = "<queue_name>";
// since ServiceBusClient implements IAsyncDisposable we create it with "await using"
await using var client = new ServiceBusClient(connectionString);

// create the sender
ServiceBusSender sender = client.CreateSender(queueName);

// create a set of messages that we can send
ServiceBusMessage[] messages = new ServiceBusMessage[]
{
    new ServiceBusMessage("First"),
    new ServiceBusMessage("Second")
};

// send the message batch
await sender.SendMessagesAsync(messages);

// create the options to use for configuring the processor
var options = new ServiceBusProcessorOptions
{
    // By default or when AutoCompleteMessages is set to true, the processor will complete the message after executing the message handler
    // Set AutoCompleteMessages to false to [settle messages](https://docs.microsoft.com/en-us/azure/service-bus-messaging/message-transfers-locks-settlement#peeklock) on your own.
    // In both cases, if the message handler throws an exception without settling the message, the processor will abandon the message.
    AutoCompleteMessages = false,

    // I can also allow for multi-threading
    MaxConcurrentCalls = 2
};

// create a processor that we can use to process the messages
await using ServiceBusProcessor processor = client.CreateProcessor(queueName, options);

// configure the message and error handler to use
processor.ProcessMessageAsync += MessageHandler;
processor.ProcessErrorAsync += ErrorHandler;

async Task MessageHandler(ProcessMessageEventArgs args)
{
    string body = args.Message.Body.ToString();
    Console.WriteLine(body);

    // we can evaluate application logic and use that to determine how to settle the message.
    await args.CompleteMessageAsync(args.Message);
}

Task ErrorHandler(ProcessErrorEventArgs args)
{
    // the error source tells me at what point in the processing an error occurred
    Console.WriteLine(args.ErrorSource);
    // the fully qualified namespace is available
    Console.WriteLine(args.FullyQualifiedNamespace);
    // as well as the entity path
    Console.WriteLine(args.EntityPath);
    Console.WriteLine(args.Exception.ToString());
    return Task.CompletedTask;
}

// start processing
await processor.StartProcessingAsync();

// since the processing happens in the background, we add a Console.ReadKey to allow the processing to continue until a key is pressed.
Console.ReadKey();

Authenticating with Azure.Identity

The Azure Identity library provides easy Azure Active Directory support for authentication.

// Create a ServiceBusClient that will authenticate through Active Directory
string fullyQualifiedNamespace = "yournamespace.servicebus.windows.net";
await using var client = new ServiceBusClient(fullyQualifiedNamespace, new DefaultAzureCredential());

Working with Sessions

Sessions provide a mechanism for grouping related messages. In order to use sessions, you need to be working with a session-enabled entity.

Registering with ASP.NET Core dependency injection

To inject ServiceBusClient as a dependency in an ASP.NET Core app, install the Azure client library integration for ASP.NET Core package.

dotnet add package Microsoft.Extensions.Azure

Then register the client where your services are configured. For ASP.NET Core applications, this is often directly in Program.cs or the StartupConfigureServices method:

public void ConfigureServices(IServiceCollection services)
{
    services.AddAzureClients(builder =>
    {
        builder.AddServiceBusClient("<< SERVICE BUS CONNECTION STRING >>");
    });

    // Register other services, controllers, and other infrastructure.
}

For applications that prefer using a shared Azure.Identity credential for their clients, registration looks slightly different:

public void ConfigureServices(IServiceCollection services)
 {
     services.AddAzureClients(builder =>
     {
         // This will register the ServiceBusClient using an Azure Identity credential.
         builder.AddServiceBusClientWithNamespace("<< YOUR NAMESPACE >>.servicebus.windows.net");

         // By default, DefaultAzureCredential is used, which is likely desired for most
         // scenarios. If you need to restrict to a specific credential instance, you could
         // register that instance as the default credential instead.
         builder.UseCredential(new ManagedIdentityCredential());
     });

     // Register other services, controllers, and other infrastructure.
 }

It is also possible to register sub-clients, such as ServiceBusSender and ServiceBusReceiver with DI using the registered ServiceBusClient instance. For example, to register a sender for each queue that belongs to the namespace:

public async Task ConfigureServicesAsync(IServiceCollection services)
{
    // Query the available queues for the Service Bus namespace.
    var adminClient = new ServiceBusAdministrationClient("<< SERVICE BUS CONNECTION STRING >>");
    var queueNames = new List<string>();

    // Because the result is async, they need to be captured to a standard list to avoid async
    // calls when registering.  Failure to do so results in an error with the services collection.
    await foreach (var queue in adminClient.GetQueuesAsync())
    {
        queueNames.Add(queue.Name);
    }

    // After registering the ServiceBusClient, register a named factory for each
    // queue.  This allows them to be lazily created and managed as singleton instances.

    services.AddAzureClients(builder =>
    {
        builder.AddServiceBusClient("<< SERVICE BUS CONNECTION STRING >>");

        foreach (var queueName in queueNames)
        {
            builder.AddClient<ServiceBusSender, ServiceBusClientOptions>((_, _, provider) =>
                provider
                    .GetService<ServiceBusClient>()
                    .CreateSender(queueName)
            )
            .WithName(queueName);
        }
    });

    // Register other services, controllers, and other infrastructure.
}

Because the senders are named for their associated queue, when injecting, you don't bind to them directly. Instead, you'll bind to a factory that can be used to retrieve the named sender:

public class ServiceBusSendingController : ControllerBase
{
    private readonly ServiceBusSender _sender;

    public ServiceBusSendingController(IAzureClientFactory<ServiceBusSender> serviceBusSenderFactory)
    {
        // Though the method is called "CreateClient", the factory will manage the sender as a
        // singleton, creating a new instance only on the first use.
        _sender = serviceBusSenderFactory.CreateClient("<< QUEUE NAME >>");
    }
}

For more details and examples, see Dependency injection with the Azure SDK for .NET.

Troubleshooting

Please refer to the Service Bus Troubleshooting Guide.

Next steps

Beyond the introductory scenarios discussed, the Azure Service Bus client library offers support for additional scenarios to help take advantage of the full feature set of the Azure Service Bus service. In order to help explore some of these scenarios, the Service Bus client library offers a project of samples to serve as an illustration for common scenarios. Please see the samples README for details.

Contributing

This project welcomes contributions and suggestions. Most contributions require you to agree to a Contributor License Agreement (CLA) declaring that you have the right to, and actually do, grant us the rights to use your contribution. For details, visit https://cla.microsoft.com.

When you submit a pull request, a CLA-bot will automatically determine whether you need to provide a CLA and decorate the PR appropriately (e.g., label, comment). Simply follow the instructions provided by the bot. You will only need to do this once across all repos using our CLA.

This project has adopted the Microsoft Open Source Code of Conduct. For more information see the Code of Conduct FAQ or contact opencode@microsoft.com with any additional questions or comments.

Please see our contributing guide for more information.

Product Compatible and additional computed target framework versions.
.NET net5.0 was computed.  net5.0-windows was computed.  net6.0 was computed.  net6.0-android was computed.  net6.0-ios was computed.  net6.0-maccatalyst was computed.  net6.0-macos was computed.  net6.0-tvos was computed.  net6.0-windows was computed.  net7.0 was computed.  net7.0-android was computed.  net7.0-ios was computed.  net7.0-maccatalyst was computed.  net7.0-macos was computed.  net7.0-tvos was computed.  net7.0-windows was computed.  net8.0 was computed.  net8.0-android was computed.  net8.0-browser was computed.  net8.0-ios was computed.  net8.0-maccatalyst was computed.  net8.0-macos was computed.  net8.0-tvos was computed.  net8.0-windows was computed. 
.NET Core netcoreapp2.0 was computed.  netcoreapp2.1 was computed.  netcoreapp2.2 was computed.  netcoreapp3.0 was computed.  netcoreapp3.1 was computed. 
.NET Standard netstandard2.0 is compatible.  netstandard2.1 was computed. 
.NET Framework net461 was computed.  net462 was computed.  net463 was computed.  net47 was computed.  net471 was computed.  net472 was computed.  net48 was computed.  net481 was computed. 
MonoAndroid monoandroid was computed. 
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Xamarin.iOS xamarinios was computed. 
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NuGet packages (377)

Showing the top 5 NuGet packages that depend on Azure.Messaging.ServiceBus:

Package Downloads
Microsoft.Azure.WebJobs.Extensions.ServiceBus

Microsoft Azure WebJobs SDK ServiceBus Extension

MassTransit.Azure.ServiceBus.Core

MassTransit Azure Service Bus Core transport support; MassTransit provides a developer-focused, modern platform for creating distributed applications without complexity.

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HealthChecks.AzureServiceBus is the health check package for Azure Service Bus Queues and Topics.

Microsoft.Azure.Functions.Worker.Extensions.ServiceBus

Azure Service Bus extensions for .NET isolated functions

Omnia.Fx.NetCore

Package Description

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Showing the top 5 popular GitHub repositories that depend on Azure.Messaging.ServiceBus:

Repository Stars
bitwarden/server
Bitwarden infrastructure/backend (API, database, Docker, etc).
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Open-source web application framework for ASP.NET Core! Offers an opinionated architecture to build enterprise software solutions with best practices on top of the .NET. Provides the fundamental infrastructure, cross-cutting-concern implementations, startup templates, application modules, UI themes, tooling and documentation.
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7.0.0-preview.6 25,559 8/18/2020
7.0.0-preview.4 14,438 7/7/2020
7.0.0-preview.3 2,113 6/8/2020
7.0.0-preview.2 4,145 5/4/2020
7.0.0-preview.1 1,123 4/7/2020