CockroachDB is a cloud-native SQL database for building global, scalable cloud services that survive disasters.
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- What is CockroachDB?
- Docs
- Quickstart
- Client Drivers
- Deployment
- Need Help?
- Contributing
- Design
- Comparison with Other Databases
- See Also
CockroachDB is a distributed SQL database built on a transactional and strongly-consistent key-value store. It scales horizontally; survives disk, machine, rack, and even datacenter failures with minimal latency disruption and no manual intervention; supports strongly-consistent ACID transactions; and provides a familiar SQL API for structuring, manipulating, and querying data.
For more details, see our FAQ and original design document.
CockroachDB is production-ready. See our 1.1 milestone for a list of features planned or in development.
For guidance on installation, development, deployment, and administration, see our User Documentation.
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Start a local cluster and talk to it via the built-in SQL client.
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Use a PostgreSQL-compatible driver or ORM to build an app with CockroachDB.
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Explore core features, such as data replication, automatic rebalancing, and fault tolerance and recovery.
CockroachDB supports the PostgreSQL wire protocol, so you can use any available PostgreSQL client drivers to connect from various languages.
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For recommended drivers that we've tested, see Install Client Drivers.
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For tutorials using these drivers, as well as supported ORMs, see Build an App with CockroachDB.
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Manual Deployment - Steps to deploy a CockroachDB cluster manually on multiple machines.
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Cloud Deployment - Guides for deploying CockroachDB on various cloud platforms.
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Orchestration - Guides for running CockroachDB with popular open-source orchestration systems.
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Troubleshooting documentation - Learn how to troubleshoot common errors, cluster and node setup, and SQL query behavior, and how to use debug and error logs.
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CockroachDB Forum and Stack Overflow - Ask questions, find answers, and help other users.
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Join us on Gitter - This is the most immediate way to connect with CockroachDB engineers.
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For filing bugs, suggesting improvements, or requesting new features, help us out by opening an issue.
We're an open source project and welcome contributions.
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See CONTRIBUTING.md to get your local environment set up.
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Take a look at our open issues, in particular those with the helpwanted label.
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Review our style guide and follow our code reviews to learn about our style and conventions.
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Make your changes according to our code review workflow.
This is an overview. For an in-depth discussion of the design and architecture, see the full design doc.
For another quick design overview, see the CockroachDB tech talk slides.
CockroachDB is a distributed SQL database built on top of a transactional and consistent key:value store.
The primary design goals are support for ACID transactions, horizontal scalability and survivability, hence the name.
It aims to tolerate disk, machine, rack, and even datacenter failures with minimal latency disruption and no manual intervention.
CockroachDB nodes are symmetric; a design goal is homogeneous deployment (one binary) with minimal configuration.
CockroachDB implements a single, monolithic sorted map from key to value where both keys and values are byte strings (not unicode).
The map is composed of one or more ranges and each range is backed by data stored in RocksDB (a variant of LevelDB), and is replicated to a total of three or more CockroachDB servers. This enables CockroachDB to scale linearly — theoretically up to 4 exabytes (4E) of logical data.
Ranges are defined by start and end keys. Ranges are merged and split
to maintain total byte size within a globally configurable min/max
size interval. Range sizes default to target 64M in order to
facilitate quick splits and merges and to distribute load at hotspots
within a key range. Range replicas are intended to be located in
disparate datacenters for survivability (e.g. { US-East, US-West, Japan }, { Ireland, US-East, US-West} , { Ireland, US-East, US-West, Japan, Australia }).
Single mutations to ranges are mediated via an instance of a distributed consensus algorithm to ensure consistency. We’ve chosen to use the Raft consensus algorithm. All consensus state is also stored in RocksDB.
A single logical mutation may affect multiple key/value pairs. Logical mutations have ACID transactional semantics. If all keys affected by a logical mutation fall within the same range, atomicity and consistency are guaranteed by Raft; this is the fast commit path. Otherwise, a non-locking distributed commit protocol is employed between affected ranges.
CockroachDB provides snapshot isolation (SI) and serializable snapshot isolation (SSI) semantics, allowing externally consistent, lock-free reads and writes--both from an historical snapshot timestamp and from the current wall clock time. SI provides lock-free reads and writes but still allows write skew. SSI eliminates write skew, but introduces a performance hit in the case of a contentious system. SSI is the default isolation; clients must consciously decide to trade correctness for performance. CockroachDB implements a limited form of linearalizability, providing ordering for any observer or chain of observers.
Similar to Spanner directories, CockroachDB allows configuration of arbitrary zones of data. This allows replication factor, storage device type, and/or datacenter location to be chosen to optimize performance and/or availability. Unlike Spanner, zones are monolithic and don’t allow movement of fine grained data on the level of entity groups.
To see how key features of CockroachDB stack up against other databases, visit the CockroachDB in Comparison page on our website.
- Tech Talks by CockroachDB founders and engineers
- The CockroachDB User documentation
- The CockroachDB Blog
- Key Design documents: