- Queues using pull model: • Storage queues • Service bus • Event Hubs • Azure IoT Hub
- Queues using push model: • Event grid
- 💡 Queues using pull model can be integrated with Event grid to push the events.
CloudStorageAccount storageAccount = CloudStorageAccount.Parse(CloudConfigurationManager.GetSetting("StorageConnectionString"));
CloudQueueClient queueClient = storageAccount.CreateCloudQueueClient();
CloudQueue queue = queueClient.GetQueueReference("myqueue");
queue.CreateIfNotExists();
CloudQueueMessage message = new CloudQueueMessage("Hello, World");
queue.AddMessage(message);- Peek:
CloudQueueMessage peekedMessage = queue.PeekMessage(); - Read & dequeue
- Get message (message becomes invisible for 30 seconds):
CloudQueueMessage retrievedMessage = queue.GetMessage(); - Delete message to dequeue:
retrievedMessage.DeleteMessage(retrievedMessage);
- Get message (message becomes invisible for 30 seconds):
- PaaS for web applications.
- Managed messaging infrastructure across private & public cloud.
- Uses pull model, can be integrated with Event Grid to have push model
- Extends Storage queues with middlewares, publish/subscribe messaging, load balancing, FIFO.
- Can be used to connect on-prem with cloud or cloud to cloud.
- Communication mechanisms
- Queues (simple queues)
- Each queue acts as broker (intermediary) that stores messages until sent.
- One directional broker: Message is sent to single recipients.
- Topics (publish-and-subscribe)
- One-directional broker: single topic can have multiple subscriptions.
- Can use filters
- Relays (connects with direct communication)
- Bidirectional communications
- No storage or broker: just passes messages to the destination.
- Queues (simple queues)
- Namespaces
- Application scoped container for all messaging components.
- Can have multiple queues & topics.
- Can have different communication mechanisms
- Messages
- Decouples applications.
- Enables 1:n relationships with topics & subscriptions
- Message sessions enables message ordering or deferral.
- Decouples applications: improves scalability and reliability.
- Queues
- Offers FIFO with ordering + timestamps or more competing consumers.
- Messages are delivered in pull mode, held in redundant storage.
- Using C#
-
Send batch to queue
QueueClient queueClient = new QueueClient(ServiceBusConnectionString, QueueName); string messageBody = $"First Message"; Message message = new Message(Encoding.UTF8.GetBytes(messageBody)); await queueClient.SendAsync(message); var messages = new List<Message>(); for (int i = 0; i < 10; i++) { var message = new Message(Encoding.UTF8.GetBytes($"Message {i:00}")}; messages.Add(message); } await queueClient.SendBatchAsync(messages);
-
Handle a message
- In client SDK, you have handler callback you call either
CompleteAsyncorAbandonAsync(you receive the message again)
- In client SDK, you have handler callback you call either
-
- Create namespaces where pub/subs will meet
- Provides a service + security boundary.
- Can be integrated with Azure Relay
- Integrates on-premises communication easily.
- Less intrusive than VPN.
- Traditional one-way, request/response, and peer-to-peer communication
- Event distribution at internet-scope to enable publish/subscribe scenarios
- Bi-directional and unbuffered socket communication across network boundaries.
- The name provides a unique identifier for the object. For example,
sbces12345.servicebus.windows.net
- Create a queue
- You can select: • Message time to live • Lock duration • Duplicate detection (duplicates won't be accepted) • Dead lettering (hold messages can't be delivered in another queue) • Sessions (guarantees FIFO) • Partitioning.
- 📝 Receiving an event
ReceivesAndDelete- Simplest, ok if system can tolerate if a message is missing if it can't be handled
PeekLockCompleteAsync=> Message is handled & deletedAbandonAsync=> Re-queued
- Temporal decoupling
- Producers (senders) and consumers (receivers) do not have to be sending and receiving messages at the same time, because messages are stored durably in the queue.
- Load leveling
- Producers consumers send & receive messages at different rates.
- You don't have to pay for a system that is underutilized part of the time.
- Loose coupling
- Resilience because messages are durable until they reach the worker.
- Load balancing
- Bring on more workers as the queue increases.
- Topics and subscriptions
- One to many (receivers)
- Messages can be filtered in topics
- Other features
- Auto-forwarding
- Batching
- Scheduled delivery (delayed processing)
- Nessage deferral
- Premium
- Fixed size
- Predictable performance
- Up-down scaling
- Messages up to 1 MB
- Standard
- Elastic
- Auto-scaling
- Message size up to 256 KB
- Metrics
- Request metrics counts the number of requests.
- Message metrics counts the messages (active, incoming, outgoing etc)
- Connection metrics active/opened/closed messages
- Resource usage metrics in Premium: CPU/memory size usage per namespace.
- Diagnostics Logs
- E.g. •
ActivityId•EventName•resourceId•SubscriptionId•EventTimeString•EventProperties•Status•Caller•category(=operationalLogs)
- E.g. •
- Service buses are built on top of storage queues and are more advanced:
- Clients can use AMQP (ISO standard for queueing)
- FIFO is guaranteed with sessions.
- And other features such as batch send, automatic dead lettering, message auto-forwarding, message groups, duplicate detection, sessions, transactions, duplicate detection, durable publish/subscribe.
- In storage queues is REST only, FIFO is not guaranteed, lease/lock is on message level (while it's on queue level in service buses).
- iPaaS: Integration Platform as a Service
- Fully managed, http-based event routing service for events.
- It connects and integrates all Azure services.
- You can create events in Events blade of resources (e.g. blob storage)
- Eliminate polling because it's expensive.
- Long polling: Server waits until the data is available instead of empty directly.
- it is very expensive in terms of CPU, memory and bandwidth
- Long polling: Server waits until the data is available instead of empty directly.
- Concepts
- Event Publishers (sources) => (through topics) Event Grid => (through subscriptions) Event Handlers
- Topic: Endpoint where the source sends events.
- Event Subscription: what you're interested in receiving
- Can be filtered
- Can have expiration date.
- Batching is supported (array of events) and recommended.
- Use case example:
- Ops automation: New VM created or SQL DB spun up => check whether configurations are compliant, tag, file work items etc.
- You can use custom events
- Get easy to use UI
- Native integrated event handlers
- Uniform consumption of events
- Uses pub/sub model.
- Can send events to multiple recipients
- Pricing:
- Pay by number of operations
Published events + delivery attempts - monthly free grant (100k) = total operations x $0.60
- Big data streaming platform and event ingestion service.
- Event ingestion
- "Front door" for an event pipeline
- Sits between publishers and consumers.
- Event ingestion
- Seamless integration with data + analytics services inside/outside Azure.
- Key components
- Event Producers
- Can publish using HTTPS, AMQP 1.0 or Apache Kafka.
- Partitions
- Views of consumers (state + position + offsets)
- Throughput units
- Prepurchased units to control capacity of EventHubs
- Event receivers
- Connect via AMQP 1.0.
- Event Producers
- Can be integrated Azure Stream Analytics
- Azure Stream Analytics: PaaS for parallel Complex Event Processing (CEP) pipelines for BI.
- Central message hub for bidirectional communication between IoT application and the devices it manages.
- Use cases include device to cloud telemetry, file upload from devices, request-reply.
- You can run Azure services (Azure Functions, Azure Stream Analytics, Azure Machine Learning, ..), or your own code on-prem on devices with remote cloud monitoring & management
- EventHubs vs Azure IoT Hub
- Azure IoT Hub leverages Event Hubs for its telemetry flow path
- Both support the ingestion of data with low latency and high reliability