Azure Functions binding expression patterns

One of the most powerful features of triggers and bindings is binding expressions. In the function.json file and in function parameters and code, you can use expressions that resolve to values from various sources.

Most expressions are identified by wrapping them in curly braces. For example, in a queue trigger function, {queueTrigger} resolves to the queue message text. If the path property for a blob output binding is container/{queueTrigger} and the function is triggered by a queue message HelloWorld, a blob named HelloWorld is created.

Types of binding expressions

Binding expressions - app settings

As a best practice, secrets and connection strings should be managed using app settings, rather than configuration files. This limits access to these secrets and makes it safe to store files such as function.json in public source control repositories.

App settings are also useful whenever you want to change configuration based on the environment. For example, in a test environment, you may want to monitor a different queue or blob storage container.

App setting binding expressions are identified differently from other binding expressions: they are wrapped in percent signs rather than curly braces. For example if the blob output binding path is %Environment%/newblob.txt and the Environment app setting value is Development, a blob will be created in the Development container.

When a function is running locally, app setting values come from the local.settings.json file.

Note

The connection property of triggers and bindings is a special case and automatically resolves values as app settings, without percent signs.

The following example is an Azure Queue Storage trigger that uses an app setting %input_queue_name% to define the queue to trigger on.

{
  "bindings": [
    {
      "name": "order",
      "type": "queueTrigger",
      "direction": "in",
      "queueName": "%input_queue_name%",
      "connection": "MY_STORAGE_ACCT_APP_SETTING"
    }
  ]
}

You can use the same approach in class libraries:

[FunctionName("QueueTrigger")]
public static void Run(
    [QueueTrigger("%input_queue_name%")]string myQueueItem, 
    ILogger log)
{
    log.LogInformation($"C# Queue trigger function processed: {myQueueItem}");
}

Trigger file name

The path for a Blob trigger can be a pattern that lets you refer to the name of the triggering blob in other bindings and function code. The pattern can also include filtering criteria that specify which blobs can trigger a function invocation.

For example, in the following Blob trigger binding, the path pattern is sample-images/{filename}, which creates a binding expression named filename:

{
  "bindings": [
    {
      "name": "image",
      "type": "blobTrigger",
      "path": "sample-images/{filename}",
      "direction": "in",
      "connection": "MyStorageConnection"
    },
    ...

The expression filename can then be used in an output binding to specify the name of the blob being created:

    ...
    {
      "name": "imageSmall",
      "type": "blob",
      "path": "sample-images-sm/{filename}",
      "direction": "out",
      "connection": "MyStorageConnection"
    }
  ],
}

Function code has access to this same value by using filename as a parameter name:

// C# example of binding to {filename}
public static void Run(Stream image, string filename, Stream imageSmall, ILogger log)  
{
    log.LogInformation($"Blob trigger processing: {filename}");
    // ...
} 

The same ability to use binding expressions and patterns applies to attributes in class libraries. In the following example, the attribute constructor parameters are the same path values as the preceding function.json examples:

[FunctionName("ResizeImage")]
public static void Run(
    [BlobTrigger("sample-images/{filename}")] Stream image,
    [Blob("sample-images-sm/{filename}", FileAccess.Write)] Stream imageSmall,
    string filename,
    ILogger log)
{
    log.LogInformation($"Blob trigger processing: {filename}");
    // ...
}

You can also create expressions for parts of the file name. In the following example, function is triggered only on file names that match a pattern: anyname-anyfile.csv

{
    "name": "myBlob",
    "type": "blobTrigger",
    "direction": "in",
    "path": "testContainerName/{date}-{filetype}.csv",
    "connection": "OrderStorageConnection"
}

For more information on how to use expressions and patterns in the Blob path string, see the Storage blob binding reference.

Trigger metadata

In addition to the data payload provided by a trigger (such as the content of the queue message that triggered a function), many triggers provide additional metadata values. These values can be used as input parameters in C# and F# or properties on the context.bindings object in JavaScript.

For example, an Azure Queue storage trigger supports the following properties:

  • QueueTrigger - triggering message content if a valid string
  • DequeueCount
  • ExpirationTime
  • Id
  • InsertionTime
  • NextVisibleTime
  • PopReceipt

These metadata values are accessible in function.json file properties. For example, suppose you use a queue trigger and the queue message contains the name of a blob you want to read. In the function.json file, you can use queueTrigger metadata property in the blob path property, as shown in the following example:

{
  "bindings": [
    {
      "name": "myQueueItem",
      "type": "queueTrigger",
      "queueName": "myqueue-items",
      "connection": "MyStorageConnection",
    },
    {
      "name": "myInputBlob",
      "type": "blob",
      "path": "samples-workitems/{queueTrigger}",
      "direction": "in",
      "connection": "MyStorageConnection"
    }
  ]
}

Details of metadata properties for each trigger are described in the corresponding reference article. For an example, see queue trigger metadata. Documentation is also available in the Integrate tab of the portal, in the Documentation section below the binding configuration area.

JSON payloads

In some scenarios, you can refer to the trigger payload's properties in configuration for other bindings in the same function and in function code. This requires that the trigger payload is JSON and is smaller than a threshold specific to each trigger. Typically, the payload size needs to be less than 100MB, but you should check the reference content for each trigger. Using trigger payload properties may impact the performance of your application, and it forces the trigger parameter type to be simple types like strings or a custom object type representing JSON data. It cannot be used with streams, clients, or other SDK types.

The following example shows the function.json file for a webhook function that receives a blob name in JSON: {"BlobName":"HelloWorld.txt"}. A Blob input binding reads the blob, and the HTTP output binding returns the blob contents in the HTTP response. Notice that the Blob input binding gets the blob name by referring directly to the BlobName property ("path": "strings/{BlobName}")

{
  "bindings": [
    {
      "name": "info",
      "type": "httpTrigger",
      "direction": "in",
      "webHookType": "genericJson"
    },
    {
      "name": "blobContents",
      "type": "blob",
      "direction": "in",
      "path": "strings/{BlobName}",
      "connection": "AzureWebJobsStorage"
    },
    {
      "name": "res",
      "type": "http",
      "direction": "out"
    }
  ]
}

For this to work in C# and F#, you need a class that defines the fields to be deserialized, as in the following example:

using System.Net;
using Microsoft.Extensions.Logging;

public class BlobInfo
{
    public string BlobName { get; set; }
}
  
public static HttpResponseMessage Run(HttpRequestMessage req, BlobInfo info, string blobContents, ILogger log)
{
    if (blobContents == null) {
        return req.CreateResponse(HttpStatusCode.NotFound);
    } 

    log.LogInformation($"Processing: {info.BlobName}");

    return req.CreateResponse(HttpStatusCode.OK, new {
        data = $"{blobContents}"
    });
}

In JavaScript, JSON deserialization is automatically performed.

module.exports = async function (context, info) {
    if ('BlobName' in info) {
        context.res = {
            body: { 'data': context.bindings.blobContents }
        }
    }
    else {
        context.res = {
            status: 404
        };
    }
}

Dot notation

If some of the properties in your JSON payload are objects with properties, you can refer to those directly by using dot (.) notation. This notation doesn't work for Azure Cosmos DB or Table storage bindings.

For example, suppose your JSON looks like this:

{
  "BlobName": {
    "FileName":"HelloWorld",
    "Extension":"txt"
  }
}

You can refer directly to FileName as BlobName.FileName. With this JSON format, here's what the path property in the preceding example would look like:

"path": "strings/{BlobName.FileName}.{BlobName.Extension}",

In C#, you would need two classes:

public class BlobInfo
{
    public BlobName BlobName { get; set; }
}
public class BlobName
{
    public string FileName { get; set; }
    public string Extension { get; set; }
}

Create GUIDs

The {rand-guid} binding expression creates a GUID. The following blob path in a function.json file creates a blob with a name like 50710cb5-84b9-4d87-9d83-a03d6976a682.txt.

{
  "type": "blob",
  "name": "blobOutput",
  "direction": "out",
  "path": "my-output-container/{rand-guid}.txt"
}

Current time

The binding expression DateTime resolves to DateTime.UtcNow. The following blob path in a function.json file creates a blob with a name like 2018-02-16T17-59-55Z.txt.

{
  "type": "blob",
  "name": "blobOutput",
  "direction": "out",
  "path": "my-output-container/{DateTime}.txt"
}

Binding at runtime

In C# and other .NET languages, you can use an imperative binding pattern, as opposed to the declarative bindings in function.json and attributes. Imperative binding is useful when binding parameters need to be computed at runtime rather than design time. To learn more, see the C# developer reference or the C# script developer reference.