My blog is migrated to a new place: http://www.gridgain.com/resources/blog
Please update your bookmarks.
My blog is migrated to a new place: http://www.gridgain.com/resources/blog
Please update your bookmarks.
I would like to clarify definitions for the following technologies:
These three terms are, surprisingly, often used interchangeably and yet technically and historically they represent very different products and serve different, sometimes very different, use cases.
It’s also important to note that there’s no specifications or industry standards on what cache, or data grid or database should be (unlike java application servers and JEE, for example). There was and still is an attempt to standardize caching via JSR107 but it has been years (almost a decade) in the making and it is hopelessly outdated by now (I’m on the expert group).
First of all, let me clarify that I am discussing caches, data grids and databases in the context of in-memory, distributed architectures. Traditional disk-based databases and non-distributed in-memory caches or databases are out of scope for this article.
Chronologically, caches, data grids and databases were developed in that order: starting from simple caching to more complex data grids and finally to distributed in-memory databases. The first distributed caches appeared in the late 1990s, data grids emerged around 2002-2003 and in-memory databases have really came to the forefront in the last 5 years.
All of these technologies are enjoying a significant boost in interest in the last couple years thanks to explosive growth in-memory computing in general fueled by 30% YoY price reduction for DRAM and cheaper Flash storage.
Despite the fact that I believe that distributed caching is rapidly going away, I still think it’s important to place it in its proper historical and technical context along with data grids and databases.
The primary use case for caching is to keep frequently accessed data in process memory to avoid constantly fetching this data from disk, which leads to the High Availability (HA) of that data to the application running in that process space (hence, “in-memory” caching).
Most of the caches were built as distributed in-memory key/value stores that supported a simple set of ‘put’ and ‘get’ operations and optionally some sort of read-through and write-through behavior for writing and reading values to and from underlying disk-based storage such as an RDBMS. Depending on the product, additional features like ACID transactions, eviction policies, replication vs. partitioning, active backups, etc. also became available as the products matured.
These fundamental data management capabilities of distributed caches formed the foundation for the technologies that came later and were built on top of them such as In-Memory Data Grids.
The feature of data grids that distinguishes them from distributed caches was their ability to support co-location of computations with data in a distributed context and consequently provided the ability to move computation to data. This capability was the key innovation that addressed the demands of rapidly growing data sets that made moving data to the application layer increasing impractical. Most of the data grids provided some basic capabilities to move the computations to the data.
This new and very disruptive capability also marked the start of the evolution of in-memory computing away from simple caching to a bona-fide modern system of record. This evolution culminated in today’s In-Memory Databases.
The feature that distinguishes in-memory databases over data grids is the addition of distributed MPP processing based on standard SQL and/or MapReduce, that allows to compute over data stored in-memory across the cluster.
Just as data grids were developed in response to rapidly growing data sets and the necessity to move computations to data, in-memory databases were developed to respond to the growing complexities of data processing. It was no longer enough to have simple key-based access or RPC type processing. Distributed SQL, complex indexing and MapReduce-based processing across TBs of data in-memory are necessary tools for today’s demanding data processing.
Adding distributed SQL and/or MapReduce type processing required a complete re-thinking of data grids, as focus has shifted from pure data management to hybrid data and compute management.
What is common about Oracle and SAP when it comes to In-Memory Computing? Both see this technology as merely a high performance addition to SQL-based database products. This is shortsighted and misses a significant point.
It is interesting to note that as the NoSQL movement sails through the “trough of disillusionment,” traditional SQL and transactional datastores are re-gaining some of the attention. But, importantly, the return to SQL, even based on in-memory technology, is limiting for many newer payload types. In-Memory Computing will play a role which is much more significant than that of a mere SQL database accelerator.
Let’s take high performance computations as an example. Use cases abound: anything from traditional MonteCarlo simulations, video and audio processing, to NLP and image processing software. All can benefit greatly from in-memory processing and gain critical performance improvements – yet for systems like this a SQL database is of little, if any, help at all. In fact, SQL has absolutely nothing to do with these use cases – they require traditional HPC processing along the lines of MPI, MapReduce or MPP — and none of these are features of either Oracle or SAP Hana databases.
Or take streaming and CEP as another example. Tremendous growth in sensory, machine-to-machine and social data, generated in real time, makes streaming and CEP one of the fastest growing use cases for big data processing. Ability to ingest hundreds of thousands of events per seconds and process them in real time has practically nothing to do with traditional SQL databases – but everything to do with in-memory computing. In fact – these systems require a completely different approach of sliding window processing, streaming indexing and complex distributed workflow management – none of which are capabilities of either Oracle or SAP Hana.
Nonetheless, SQL processing was, is, and always will be with us. Ironically, it is now getting back on some of the pundits’ radars. For example, in data warehousing, where Hadoop can be used as a massive data store of record, SQL can play well. In-Memory Computing, however, plays a greater role than just a cache for a large datastore. New payload types require different processing approaches – and all benefit from the dramatic performance improvements brought by in-memory computing.
At GridGain, we are keenly aware of the self evident point: In-Memory Computing is much more significant than just getting a slow SQL database to go faster. Our end-to-end product suite delivers many additional benefits of in-memory computing, handles use cases that are impossible to address in the traditional database world. And there’s so much more to come.
Almost two years ago, Dmitriy and I stood in front of a white board at GridGain’s office thinking: “How can we deliver the real-time performance of GridGain’s in-memory technology to Hadoop customers without asking them rip and replace their systems and without asking them to move their datasets off Hadoop?”.
Given Hadoop’s architecture – the task seemed daunting; and it proved to be one of the more challenging engineering puzzles we have had to solve.
After two years of development, tens of thousands of lines of Java, Scala and C++ code, multiple design iterations, several releases and dozens of benchmarks later, we finally built a product that can deliver real-time performance to Hadoop customers with seamless integration and no tedious ETL. Actual customers deployments can now prove our performance claims and validate our product’s architecture.
Here’s how we did it.
Hadoop is based on two primary technologies: HDFS for storing data, and MapReduce for processing these data in parallel. Everything else in Hadoop and the Hadoop ecosystem sits atop these foundation blocks.
Originally, neither HDFS nor MapReduce were designed with real-time performance in mind. In order to deliver real-time processing without moving data out of Hadoop onto another platform, we had to improve the performance of both of these subsystems.
We decided to develop a high-performance in-memory file system which would provide 100% compatibility with HDFS and an optimized MapReduce implementation which would take advantage of this real-time file system. By doing so, we could offer all the advantages of our in-memory platform while minimizing the disruption of our customers’ existing Hadoop investments.
There are many projects and products that aim to improve Hadoop performance. Projects like HDFS2, Apache Tez, Cloudera Impala, HortonWorks Stinger, ScaleOut hServer and Apache Spark to name but a few, all aim to solve Hadoop performance issues in various ways. GridGain, puts a new spin on some of these approaches delivering unmatched performance gains while fanatically maintaining our commitment to making customers change less code and quickly get the benefits an in-memory computing platform can bring to their big data installations.
From a technology stand point GridGain’s In-Memory Hadoop Accelerator has some similarity to the architecture of Spark (optimized MapReduce), ScaleOut and HDFS2 (in-memory caching without ETL) and some features of Apache Tez (in-process execution), however, GridGain’s In-Memory Accelerator is the only product for Hadoop available today that combines the both the high performance HDFS-compatible file system and optimized in-memory MapReduce along with many other features in one fully integrated product.
First, we implemented GridGain’s In-Memory File System (GGFS) to accelerate I/O in the Hadoop stack. The original idea was that GGFS alone will be enough to gain significant performance increase. However, while we saw significant performance gains using GGFS, when working with our customers we quickly found that there were some not so obvious performance limitations to the way in which Hadoop performs MapReduce. It quickly became clear to us that GGFS alone won’t be enough but it was a critical piece that we needed to build first.
Note that you shouldn’t confuse GGFS with much slower alternatives like RAM disk. GGFS is based on our Memory-First architecture and addresses more than just the seek time of the “device”.
From the get go we designed GGFS to support both Hadoop v1 and YARN Hadoop v2. Further, we designed GGFS to work in two modes:
In primary standalone mode GGFS acts as a bona-fide Hadoop file system that is PnP compatible with the standard HDFS interface. Our customers use it to deploy a high-performance in-memory Hadoop cluster and use it as any other Hadoop file system – albeit one that trades capacity for maximum performance.
One of the great added benefits of the primary mode is that it does away with NamedNode in the Hadoop deployment. Unlike a standard Hadoop deployment that requires shared storage for primary and secondary NameNodes which is usually implemented with a complex NFS setup mounted on each NameNode machine, GGFS seamlessly utilizes GridGain’s In-Memory Database under the hood to provide completely automatic scaling and failover without any need for additional shared storage or risky Single Point Of Failure (SPOF) architectures.
Furthermore, unlike Hadoop’s master-slave design for NamedNodes that prevents Hadoop systems from scaling linearly when adding new nodes, GGFS is built on a highly scalable, natively distributed, partitioned data store which provides linear scalability and auto-discovery of new nodes joining the cluster. Removing NamedNode form the architecture enabled dramatically better performance of IO operations.
GGFS’s primary mode provides maximum performance for IO operations but requires moving data from disk-based HDFS to an memory-based GGFS (i.e. from one file system to another). While data movement may be appropriate for some use cases, we support another operating mode in which absolutely no ETL is required – no need to move data out of HDFS. In this mode, GGFS works as an intelligent secondary in-memory distributed cache over the primary disk-based HDFS file system.
In the second mode, GGFS works as an intelligent secondary in-memory distributed cache over the primary disk-based HDFS file system. In this mode GGFS supports both synchronous and asynchronous read-through and write-through to and from HDFS providing either strong consistency or better performance in exchange for relaxed consistency with absolute transparency to the user and applications running on top of it. In this mode users can manually select which set of files and/or directories should be stored in GGFS and what mode – synchronous or asynchronous – should be used for each one of them for read-through and write-through to and from HDFS.
Another interesting feature of GGFS is its smart usage of block-level or file-level caching and eviction design. When working in primary mode GGFS utilizes file level caching to ensure corruption free storage (the file is either fully in GGFS or not at all). When in secondary mode, GridGain will automatically switch to block-level caching and eviction. What we discovered when working with our customers on real-world Hadoop payloads is that files on HDFS are often accessed not uniformly, i.e. they have significant “locality” in how portions of the file is being accessed. Put another way, certain blocks of a file are accessed more frequently than others. That observation led to our block-level caching implementation for the secondary mode that enables dramatically better memory utilization since GGFS can store only the most frequently used file blocks in memory – and not entire files which can easily measure in 100GBs in Hadoop.
Caching can NOT work effectively without a sophisticated eviction management mechanism to make sure that memory is used optimally. So, we built a new and technically robust eviction mechanism into our platform. Apart from obvious eviction features, you can configure certain files to never be evicted preserving them in memory in all cases for maximum performance, for example.
To ensure seamless and continuous performance during MapReduce file scanning, we’ve implemented smart data prefetching via streaming data that is expected to be read in the nearest future to the MapReduce task ahead of time. By doing so, GGFS ensures that whenever a MapReduce task finishes reading a file block, the next file block is already available in memory. A significant performance boost was achieved here due to our proprietary Inter-Process Communication (IPC) implementation which allows GGFS to achieve throughput of up to 30Gbit/s between two processes.
Table below shows GGFS vs. HDFS (on Flash-based SSDs) benchmark results for raw IO operations:
|Benchmark||GGFS, ms.||HDFS, ms.||Boost, %|
|File Random Access||413||2931||710%|
The above tests were performed on a 10-node cluster of Dell R610 blades with Dual 8-core CPUs, running Ubuntu 12.4 OS, 10GBE network fabric and stock unmodified Apache Hadoop 2.x distribution.
As you can see from these results the IO performance difference is quite significant. However, HDFS performance as a file system is only a part of Hadoop’s overhead. Another part, no less significant, is the MapReduce overhead. That is what we addressed with In-Memory MapReduce.
Once we had our high performance in-memory file system built and tested, we turned our attention to a MapReduce implementation that would take advantage of in-memory technology.
Hadoop’s MapReduce design is one of the weakest points in Hadoop. It’s basically a inefficiently designed system when it comes to distributed processing. GridGain In-Memory MapReduce implementation relies heavily on 7 years of experience developing our widely deployed In-Memory HPC product. GridGain’s In-Memory MapReduce is designed on record-based approach vs. key-value approach of traditional MapReduce, and it enables much more streamlined parallel execution path on data stored in in-memory file system.
Furthermore, In-Memory MapReduce eliminates the standard overhead associated with the typical Hadoop job tracker polling, task tracker process creation, deployment and provisioning. All in all – GridGain’s In-Memory MapReduce is a highly optimized HPC-based implementation of the MapReduce concept enabling true low-latency data processing of data stored in GGFS.
The diagram below demonstrates the difference between a standard Hadoop MapReduce execution path and GridGain’s In-Memory MapReduce execution path:
As seen in this diagram our MapReduce implementation supports direct execution path from client to data node. Moreover, all execution in GridGain happens in-process with deployment handled automatically and transparently by GridGain.
In-Memory MapReduce also provides integration capability for MapReduce code written in any Hadoop supported language and not only in native Java or Scala. Developers can easily reuse existing C/C++/Python or any other existing MapReduce code with our In-Memory Accelerator for Hadoop to gain significant performance boost.
Finally, since we can remove task and job tracker polling, out of process execution, and the often unnecessary shuffling and sorting from MapReduce while letting our products work with a high-performance in-memory file system we can start seeing 10x – 100x performance increases on typical MapReduce payloads. This is not just theory, our tests and our customers can confirm this.
Below are the results for one of the internal tests that utilizes both In-Memory File System and In-Memory MapReduce. This test was specifically designed to show maximum GridGain’s Accelerator performance vs. stock Hadoop distribution for heavy I/O MapReduce jobs:
|Nodes||Hadoop, ms.||Hadoop + GridGain Accelerator, ms.||Boost, %|
Tests were performed on a cluster of Dell R610 blades with Dual 8-core CPUs, running Ubuntu 12.4 OS, 10GBE network fabric and stock unmodified Apache Hadoop 2.x distribution and GridGain 5.2 release.
No serious distributed system can be used without comprehensive DevOps support and In-Memory Accelerator for Hadoop comes with a comprehensive unified GUI-based management and monitoring tool called GridGain Visor. Over the last 12 months we’ve added significant support in Visor for Hadoop Accelerator.
Visor provides deep DevOps capabilities including an operations & telemetry dashboard, database and compute grid management, as well as GGFS management that provides GGFS monitoring and file management between HDFS, local and GGFS file systems.
As part of GridGain Visor, In-Memory Accelerator For Hadoop also comes with a GUI-based file system profiler, which allows you to keep track of all operations your GGFS or HDFS file systems make and identifies potential hot spots.
GGFS profiler tracks speed and throughput of reads, writes, various directory operations, for all files and displays these metrics in a convenient view which allows you to sort based on any profiled criteria, e.g. from slowest write to fastest. Profiler also makes suggestions whenever it is possible to gain performance by loading file data into in-memory GGFS.
After almost 2 years of development we have a well rounded product that can help you accelerate Hadoop MapReduce up to 100x times with minimal integration and effort. It’s based on our innovative high-performance in-memory file system and in-memory MapReduce implementation coupled with one of the best management and monitoring tools.
If you want to be able to say words “milliseconds” and “Hadoop” in one sentence – you need to take a serious look at GridGain’s In-Memory Hadoop Accelerator.
We are happy to announce the general availability release for GridGain 5.2 which includes updates to all products in the platform:
We anticipate this being the last mid-point release in the platform before we roll out 6.0 line Q114 or Q214 (we are still planning to have bi-weekly service releases going forward as usual).
During past months we’ve been working very diligently to improve the general usability of our products: from first impressions, to POCs, to production use. Despite the fact that GridGain has enjoyed a stellar record on this front for years – the platform’s size is growing rapidly (we are now at almost 4x size of the entire Hadoop codebase, for example) – and we need to make sure that size and complexity don’t overshadow the simplicity and usability our products enjoyed so far.
We’ve added many features and enhancements: better error messages, automatic configuration conflict detection, automatic backward compatibility checks, and better documentation.
Work in this direction will continue. We listen to our customers and pay attention to how they use our products. We make improvements every sprint.
One of the biggest improvement in the last 6 months is performance for non-transactional use cases. GridGain has been winning every benchmark when it comes to distributed ACID transactions – but we haven’t had same winning margins when it came to simpler, non-transactional payloads.
It’s fixed now.
We are currently running over 50 benchmarks against every competitive database and data grid products (all seven of them) and currently are winning over 95% of them with some as much as 3-4x. That includes 100% of distributed ACID transactional use cases and most of of the non-transactional use cases (EC, simple automicity, local-only transactions, etc.)
GridGain still holds a record of achieving 1 Billion TPS on 10 commodity Dell R610 blades. The records was achieved in a open tender and is verifiable. No other product has yet achieved this level of performance.
There’s plenty of exciting stuff that we’ve been working on for the past 6-9 months that will be made public early next year when GridGain 6.0 platform will roll out. Some features have trickled out to the public – but most have been kept tight for the next release.
As always, grab your free download of GridGain at http://www.gridgain.com/download and check out our constantly growing documentation center for all your screencasts, videos, white papers, and technical documentation: http://www.gridgain.com/documentation
In the last 12 months we observed a growing trend that use cases for distributed caching are rapidly going away as customers are moving up stack… in droves.
Let me elaborate by highlighting three points that when combined provide a clear reason behind this observation.
In the last 3-5 years traditional RDBMSs and new crop of simpler NewSQL/NoSQL databases have mastered the in-memory caching and now provide comprehensive caching and even general in-memory capabilities. MongoDB and CouchDB, for example, can be configured to run mostly in-memory (with plenty caveats but nonetheless). And when Oracle 12 and SAP HANA are in the game (with even more caveats) – you know it’s a mainstream already.
There’s simply less reasons today for just caching intermediate DB results in memory as data sources themselves do a pretty decent job at that, 10GB network is often fast enough and much faster IB interconnect is getting cheaper. Put it the other way, performance benefits of distributed caching relative to the cost are simpler not as big as they were 3-5 years ago.
Emerging “Caching The Cache” anti-pattern is a clear manifestation of this conundrum. And this is not only related to historically Java-based caching products but also to products like Memcached. It’s no wonder that Java’s JSR107 has been such a slow endeavor as well.
In the same time as customers moving more and more payloads to in-memory processing they are naturally starting to have bigger expectations than the simple key/value access or full-scan processing. As MPP style of processing on large in-memory data sets becoming a new “norm” these customers are rightly looking for advanced clustering, ACID distributed transactions, complex SQL optimizations, various forms of MapReduce – all with deep sub-second SLAs – as well as many other features.
Distributed caching simply doesn’t cut it: it’s a one thing to live without a distributed hash map for your web sessions – but it’s completely different story to approach mission critical enterprise data processing without transactional data center replication, comprehensive computational and data load balancing, SQL support or complex secondary indexes for MPP processing.
Apples and oranges…
And not only customers move more and more data to in-memory processing but their computational complexity grows as well. In fact, just storing data in-memory produces no tangible business value. It is the processing of that data, i.e. computing over the stored data, is what delivers net new business value – and based on our daily conversations with prospects the companies across the globe are getting more sophisticated about it.
Distributed caches and to a certain degree data grids missed that transition completely. While concentrating on data storage in memory they barely, if at all, provide any serious capabilities for MPP or MPI-based or MapReduce or SQL-based processing of the data – leaving customers scrambling for this additional functionality. What we are finding as well is that just SQL or just MapReduce, for instance, is often not enough as customers are increasingly expecting to combine the benefits of both (for different payloads within their systems).
Moreover, the tight integration between computations and data is axiomatic for enabling “move computations to the data” paradigm and this is something that simply cannot be bolted on existing distributed cache or data grid. You almost have to start form scratch – and this is often very hard for existing vendors.
And unlike the previous two points this one hits below the belt: there’s simply no easy way to solve it or mitigate it.
So, what’s next? I don’t really know what the category name will be. May be it will be Data Platforms that would encapsulate all these new requirements – may be not. Time will tell.
At GridGain we often call our software end-to-end in-memory computing platform. Instead of one do-everything product we provide several individual but highly integrated products that address every major type of payload of in-memory computing: from HPC, to streaming, to database, and to Hadoop acceleration.
It is an interesting time for in-memory computing. As a community of vendors and early customers we are going through our first serious transition from the stage where simplicity and ease of use were dominant for the early adoption of the disruptive technology – to a stage where growing adaption now brings in the more sophisticated requirements and higher customer expectations.
As vendors – we have our work cut out for us.
Excellent quick overview of GridGain Visor – unified administration, management and monitoring tool for GridGain’s suite of in-memory computing products. For those keeping score – this is one of the GridGain components that is written 100% in Scala from the ground up. Enjoy!
Or – direct link on Vimeo.