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Pocket is a storage system designed for ephemeral data sharing. Pocket provides fast, distributed and elastic storage for data with low durability requirements. The key properties of Pocket are:

  • high throughput and low latency for a wide range of object sizes
  • automatic resource scaling and rightsizing
  • intelligent data placement across multiple storage tiers

Pocket offers a serverless abstraction to storage, meaning users do not manually configure or manage storage servers. A key use-case for Pocket is ephemeral data sharing in serverless analytics, when serverless tasks need to exchange intermediate data between execution stages.

Building and Deploying Pocket from Source

To build Pocket from source execute the following steps:

cd client 
./build.sh 			# builds libcppcrail.so and libpocket.so
cd ../pocket-core
mvn -DskipTests install 	# builds crail-1.0-bin.tar.gz

For deployment, copy the shared libraries libcppcrail.so and libpocket.so together with the python scripts pocket.py, controller.py and pocket_metadata_cmds.py to one directory, and un-tar crail-1.0-bin.tar.gz into a different directory. pocket.py is the client interface applications use to store and share ephemeral data between function invocations. controller.py is the Pocket controller responsible for managing storage resources in an elastic manner. crail-1.0-bin contains the server side of the Pocket storage platform.

Running Pocket

Follow the instructions in the deploy README to set up and run a Pocket deployment on Amazon Web Services.

Follow the instructions in the microbenchmark README to run a simple example test on AWS Lambda that measures Pocket PUT, GET and metadata lookup latency.

Pocket Design

Pocket divides responsibility across a control plane, metadata plane and data plane, which can each be scaled indepdently across nodes. Pocket has a logically centralized controller which decides how to distribute data for incoming application jobs. The meatdata plane routes client requests and keeps track of data stored across nodes in the data plane.

Pocket is designed for sub-second response times. I/O operations are kept deliberatly simple and the storage tier implementation leverages low-latency, high-throughput user-level network and storage processing stacks. The controller monitors per-second cluster resource utilization across multiple dimensions (compute, network bandwidth and storage capacity) and scales cluster resource allocations to match application requirements. The controller allocates resource with the primary goal of providing high I/O performance to jobs. The secondary goals is to minimizing the resource cost.

Pocket uses multiple storage media (DRAM, Flash and HDD) to balance performance and cost, storing an application's data on the lowest cost storage media that still satisfies the application's I/O demands.

Implementation

We leverage several open source projects to implement Pocket. Pocket's metadata and data planes are based on Apache Crail. The NVMe Flash and block storage tiers are based on ReFlex. We deploy Pocket metadata and data nodes in Docker containers. Pocket's controller uses the Kubernetes container orchestration system to elastically scale the cluster based on dynamic application demands.

Pocket repository structure

  • deploy: deployment scripts and instructions to run Pocket with Kubernetes on AWS EC2
  • controller: control plane logic for automatic resource scaling
  • client: python client library for Pocket, based on the Crail C++ client
  • dockerfiles: build new Pocket container images if you modify Pocket source code
  • microbenchmark: a simple lambda latency test for Pocket
  • pocket-core: source code for Pocket metadata and data plane implementation, based on Apache Crail and ReFlex

Reference

Please refer to the Pocket OSDI'18 paper:

Ana Klimovic, Yawen Wang, Patrick Stuedi, Animesh Trivedi, Jonas Pfefferle, and Christos Kozyrakis. Pocket: Elastic Ephemeral Storage for Serverless Analytics. In Proceedings of the USENIX Symposium on Operating Systems Design and Implementation (OSDI), 2018.

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