Storlet Engine Overview

Storlet Engine Overview

At the high level the storlet engine is made of the components described below. See illustration.

The storlet middleware

The storlet middleware is a Swift WSGI middleware that intercepts storlet invocation requests and routes the input data and the computation output into and out of the Docker container where the storlet is executed. This middleware needs to be in both the proxy-server and the object-server pipelines.

The storlet middleware is written in a way that allows to extend the engine to support sandboxing technologies other then Docker. This manifests in the “storlet gateway” API which defines the functionality required from a sandbox to run storlets. Moreover, part of the storlet middleware configuration is what “storlet gateway” implementation class to load. Currently, we have a single class implementation of the API we refer to as “storlet docker gateway”.

Swift accounts

The storlet engine is tightly coupled with accounts in Swift in the following manners:

  1. In order to invoke a storlet on a data object residing in some Swift account, that account must be enabled for storlets. That is, it must have a designated user defined metadata flag on the account set to true.
  2. Each Swift account must have certain containers required by the engine. One such container is the “storlet” container, where storlets are being uploaded. Storlets uploaded to this container can be invoked on any data object in that account, given that the invoking user has read permissions to the “storlet” container.
  3. Each account has a separate Docker image (and container) where storlets are being executed. All the storlets being executed on data objects belonging to same account, will be executed in the same Docker container. This facilitates having different images for different Swift accounts. The Docker image name must be the account id to which it belongs.

The Docker image

As mentioned above there is a Docker image per account that is enabled for storlets. At a high level this image containes:

  1. A Java run time environment. This is needed when you run storlets written in Java
  2. A daemon factory. A Python process that starts as part of the Docker container bring up. This process spawns the “per storlet daemons” upon a request from the “storlet docker gateway” that runs in the context of the storlet_middleware.
  3. A storlet daemon. The storlet daemon is a generic daemon that once spawned loads a certain storlet code and awaits invocations. Different storlets, e.g. a filtering storlet and a compression storlet are loaded into different daemons. A daemon is invoked the first time a certain storlet needs to be executed. Currently we have two types of daemons, a Java daemon for loading and running Java written storlets, and a Python daemon for loading and runding Python written storlets.
  4. The storlet common jar. This is the jar used for developing storlets in Java. Amongst other things it has the definition of the invoke API the storlet must implement.

The storlet bus

The storlet bus is a communication channel between the storlet middleware in the Swift side and the factory daemon and storlet daemon in the Docker container. For each Docker container (or Swift account) there is a communication channel with the storlet factory of that container. For each storlet daemon in the container there is a communication channel on which is listens for invocations. These channels are based on unix domain sockets.

The storlet engine components illustration

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Flow

To tie everything together we illustrate an end-to-end scenario.

Writing and Deploying a storlet

The flow begins with writing a storlet followed by deploying it. writing and deploying a storlet is covered in the writing and deploying storlets guide.

Invoking a Storlet

A Storlet can be invoked on object download, upload or copy operations (GET, PUT, and COPY respectively). For the flow description lets assume that we wish to invoke the storlet on an object download. This involves doing a Swift GET request with the additional header “X-Run-Storlet” which specifies the storlet to invoke, e.g. “X-Run-Storlet: compress-1.0.jar”.

Handling the request at the proxy server

Seeing the “X-Run-Storlet” header the storlert_middleware at the proxy intercepts the request and performs a HEAD on the storlet specified by the user. This HEAD operation facilitates:

  1. Enforcing execution rights: Having access to the storlet container means that the user is allowed to invoke storlets. If the HEAD fails then the engine returns HTTP Unauthorized.
  2. Getting the storlet metadata. This metadata is later used to validate that the actual code being executed is the most updated code.

Once the HEAD succeeds, the storlet middleware adds the storlet metadata to the request and lets the request continue to flow through the proxy pipeline. The pipeline ends with with the request being routed to an object server that holds a replica of the object specified in the GET uri.

Handling the request at the object server

Seeing the “X-Run-Storlet” header the storlert_middleware at the object server intecepts the request and perform the following two phased flow:

Phase one

The first phase has to do with making sure there is a local storlet daemon running inside a Docker container for the appropriate account. In this phase the middleware performs the following:

  1. Checks whether there is a running Docker container for the account appearing in the request uri. If there isn’t one, the middleware tried to spawn it.
  2. Checks whether there is a local updated copy of the required storlet to execute. If there is no local copy or the copy is not up-to-date the middleware initiates an internal GET request for bringing it from the “storlet” container.
  3. If the local copy is updated, the middleware checks whether there is a running daemon for that storlet in the container. This is done by querying the storlet daemon over a named pipe called “factory pipe”.
  4. In case there is no running daemon the middleware asks the factory to spawn one for it. Once spawned the daemon start listening on a designated named pipe for invocations.

Phase two

In the second phase the middleware actually invokes the storlet over the request. Once there is a daemon running the middleware proceeds as follows:

  1. The middleware lets the request to continue flowing through the object server pipeline, until it gets a response. The response carries a descriptor through which the object data can be accessed.
  2. The middleware uses the storlet daemon named pipe to do the actual invocation of the storlet. The actual invocarion is done by passing along the pipe a descriptor carrying the object data as well as a descriptor for the storlet to write its output, and another descriptor for the storlet logs.
  3. Once the storlet starts writing results to the output descriptor, the sotler_middleware returns a response which carries the storlet’s output descriptor so that the output can be streamed back to proxy and to the user.

Note

The above is a simplification that highlights the major work done by the storlet engine.

Note

There are cases where the storlet is executed on the proxy. One such case is a PUT request. Executing a storlet on the proxy involves pretty much the exact steps described above.

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