tag | cafda8511ba58a6f33e45f6c91897a2e8c3cb2b2 | |
---|---|---|
tagger | Alexey Goncharuk <alexey.goncharuk@gmail.com> | Fri Apr 14 14:41:27 2017 +0300 |
object | 7e106cd093134acab1c4202a6849c177bacc909b |
Master before page memory
commit | 7e106cd093134acab1c4202a6849c177bacc909b | [log] [tgz] |
---|---|---|
author | Igor Sapego <isapego@gridgain.com> | Thu Apr 13 19:06:01 2017 +0300 |
committer | Igor Sapego <isapego@gridgain.com> | Thu Apr 13 19:06:01 2017 +0300 |
tree | a841d94d769db5931416fc936133c774126c4421 | |
parent | d298e75610e192ef1ca17fb9e678bd83db64e1a4 [diff] |
IGNITE-3581: Moved enums to separate structs for C++
The Apache Ignite In-Memory Data Fabric is a high-performance, integrated and distributed in-memory platform for computing and transacting on large-scale data sets in real-time, orders of magnitude faster than possible with traditional disk-based or flash technologies.
Apache Ignite In-Memory Data Fabric is designed to deliver uncompromised performance for a wide set of in-memory computing use cases from high performance computing, to the industry most advanced data grid, highly available service grid, and streaming.
Ignite nodes can automatically discover each other. This helps to scale the cluster when needed, without having to restart the whole cluster. Developers can also leverage from Ignite’s hybrid cloud support that allows establishing connection between private cloud and public clouds such as Amazon Web Services, providing them with best of both worlds.
Ignite data grid is an in-memory distributed key-value store which can be viewed as a distributed partitioned hash map, with every cluster node owning a portion of the overall data. This way the more cluster nodes we add, the more data we can cache.
Unlike other key-value stores, Ignite determines data locality using a pluggable hashing algorithm. Every client can determine which node a key belongs to by plugging it into a hashing function, without a need for any special mapping servers or name nodes.
Ignite data grid supports local, replicated, and partitioned data sets and allows to freely cross query between these data sets using standard SQL syntax. Ignite supports standard SQL for querying in-memory data including support for distributed SQL joins.
Our data grid offers many features, some of which are:
Ignite streaming allows to process continuous never-ending streams of data in scalable and fault-tolerant fashion. The rates at which data can be injected into Ignite can be very high and easily exceed millions of events per second on a moderately sized cluster.
Real-time data is ingested via data streamers. We offer streamers for JMS 1.1, Apache Kafka, MQTT, Twitter, Apache Flume and Apache Camel already, and we keep adding new ones every release.
The data can then be queried within sliding windows, if needed:
Distributed computations are performed in parallel fashion to gain high performance, low latency, and linear scalability. Ignite compute grid provides a set of simple APIs that allow users distribute computations and data processing across multiple computers in the cluster. Distributed parallel processing is based on the ability to take any computation and execute it on any set of cluster nodes and return the results back.
We support these features, amongst others:
Service Grid allows for deployments of arbitrary user-defined services on the cluster. You can implement and deploy any service, such as custom counters, ID generators, hierarchical maps, etc.
Ignite allows you to control how many instances of your service should be deployed on each cluster node and will automatically ensure proper deployment and fault tolerance of all the services.
Ignite File System (IGFS) is an in-memory file system allowing work with files and directories over existing cache infrastructure. IGFS can either work as purely in-memory file system, or delegate to another file system (e.g. various Hadoop file system implementations) acting as a caching layer.
In addition, IGFS provides API to execute map-reduce tasks over file system data.
Ignite supports complex data structures in a distributed fashion:
AtomicLong
and AtomicReference
.CountDownLatch
.Distributed messaging allows for topic based cluster-wide communication between all nodes. Messages with a specified message topic can be distributed to all or sub-group of nodes that have subscribed to that topic.
Ignite messaging is based on publish-subscribe paradigm where publishers and subscribers are connected together by a common topic. When one of the nodes sends a message A for topic T, it is published on all nodes that have subscribed to T.
Distributed events allow applications to receive notifications when a variety of events occur in the distributed grid environment. You can automatically get notified for task executions, read, write or query operations occurring on local or remote nodes within the cluster.
Our Hadoop Accelerator provides a set of components allowing for in-memory Hadoop job execution and file system operations.
An alternate high-performant implementation of job tracker which replaces standard Hadoop MapReduce. Use it to boost your Hadoop MapReduce job execution performance.
A Hadoop-compliant IGFS File System implementation over which Hadoop can run over in plug-n-play fashion and significantly reduce I/O and improve both, latency and throughput.
An implementation of SecondaryFileSystem
. This implementation can be injected into existing IGFS allowing for read-through and write-through behavior over any other Hadoop FileSystem implementation (e.g. HDFS). Use it if you want your IGFS to become an in-memory caching layer over disk-based HDFS or any other Hadoop-compliant file system.
Apache Ignite provides an implementation of Spark RDD abstraction which allows to easily share state in memory across Spark jobs. The main difference between native Spark RDD
and IgniteRDD
is that Ignite RDD provides a shared in-memory view on data across different Spark jobs, workers, or applications, while native Spark RDD cannot be seen by other Spark jobs or applications.
Ignite.NET
Ignite C++
For information on how to get started with Apache Ignite please visit: Getting Started.
You can find the full Apache Ignite documentation here: Full documentation.