MongoDB 3.0 WiredTiger Compression and Performance
MongoDB3.0中的压缩选项
在MongoDB 3.0中,WiredTiger为集合提供三个压缩选项:
- 无压缩
- Snappy(默认启用) – 很不错的压缩,有效利用资源
- zlib(类似gzip) – 出色的压缩,但需要占用更多资源
有索引的两个压缩选项:
- 无压缩
- 前缀(默认启用) – 良好的压缩,资源的有效利用
请记住哪些适用于MongoDB的3.0所有压缩选项:
- 随机数据不能压缩
- 二进制数据不能压缩(它可能已经被压缩)
- 文本压缩效果特别好
- 对于文件中的字段名压缩效果特别好(尤其对短字段名来说)
官方说法:
Compression
With WiredTiger, MongoDB supports compression for all collections and indexes. Compression minimizes storage use at the expense of additional CPU.
By default, WiredTiger uses block compression with the snappy compression library for all collections andprefix compression for all indexes.
For collections, block compression with zlib is also available. To specify an alternate compression algorithm or no compression, use the storage.wiredTiger.collectionConfig.blockCompressor setting.
For indexes, to disable prefix compression, use thestorage.wiredTiger.indexConfig.prefixCompression setting.
Compression settings are also configurable on a per-collection and per-index basis during collection and index creation. See Specify Storage Engine Options and db.collection.createIndex() storageEngine option.
For most workloads, the default compression settings balance storage efficiency and processing requirements.
The WiredTiger journal is also compressed by default. For information on journal compression, see Journal.
MongoDB 3.0 WiredTiger Compression and Performance
One of the most exciting developments over the lifetime of MongoDB must be the inclusion of the WiredTiger storage engine in MongoDB 3.0. Its very design and core architecture are legions ahead of the current MMAPv1 engine and comparable to most modern day storage engines for various relational and non-relational stores. One of the most compelling features of the WiredTiger storage engine is compression. Let's talk a bit more about performance and compression.
Configuration
MongoDB 3.0 allows the user to configure different storage engines through the storage engine API. For the first time ever we have an amazing array of options for setting up MongoDB to match our workloads and use-cases. To run WiredTiger the version must be 3.0 or higher and the configuration file must call for WiredTiger. For example:
storage:
dbPath: "/data/mongodb"
journal:
enabled: true
engine: "wiredTiger"
wiredTiger:
engineConfig:
cacheSizeGB: 99
journalCompressor: none
directoryForIndexes: "/indexes/mongodb/"
collectionConfig:
blockCompressor: snappy
indexConfig:
prefixCompression: true
systemLog:
destination: file
path: "/tmp/mongodb.log"
logAppend: true
processManagement:
fork: true
net:
port: 9005
unixDomainSocket:
enabled : true
There are a lot of new configuration options in 3.0 so let's take the notable options one by one.
-
storage.engine. The setting ensures we are using the WiredTiger storage engine. Should be set to "wiredTiger" to use the WiredTiger engine. It can also be set to "mmapv1". MMAPv1 is the default in 3.0, but in MongoDB 3.1 (potentially) this will change to wiredTiger.
-
storage.wiredTiger.engineConfig.cacheSizeGB. This sets up a page cache for WiredTiger to cache frequently used data and index blocks in GB. If this is not specified, MongoDB will automatically assign memory up to about 50% of total addressable memory.
-
storage.wiredTiger.engineConfig.directoryForIndexes. Yes! We can now store indexes on a separate block device. This should help DBAs size, capacity plan, and augment performance as needed.
-
storage.wiredTiger.collectionConfig.blockCompressor. This can be set to 'snappy' or 'zlib'. Snappy having higher performance and lower compression than zlib. Some more detail later on compression algorithms.
-
storage.wiredTiger.indexConfig.prefixCompression. This setting enables prefix compression for indexes. Valid options are true|false and the default is true.
Let's talk performance
WiredTiger is going to be much faster than MMAPv1 for almost all workloads. Its real sweet spot is highly concurrent and/or workloads with lots of updates. This may surprise some folks because traditionally compression is a trade off. Add compression, lose performance. That is normally true, but a couple of things need to be considered here. One, we are comparing the MMAPv1 engine with database level locking to WiredTiger with document level locking. Any reasonable concurrent workload is almost always bound by locking and seldom by pure system level resources. Two, WiredTiger does page level compression. More on this later.
There are a few things that make WiredTiger faster other than its locking scope. WiredTiger also has a streamlined process for free space lookups and management and it has a proper cache with its own I/O components.
Because WiredTiger allows for compression, a common worry is the potential for overall performance impact. But as you can see, in a practical sense this worry is mostly unfounded.
A couple graphs for relative performance difference for sysbench-mongodb. It should be noted that WiredTiger is using defaults in this configuration, including snappy compression and index prefix compression.
Let's break it down a bit more:
The relative CPU usage for each:
Let's talk more about compression
Compressing data inside a database is tricky. WiredTiger does a great job at handling compression because of its sophisticated management approach:
The cache generally stores uncompressed changes (the exception is for very large documents). The default snappy compression is fairly straightforward: it gathers data up to a maximum of 32KB, compresses it, and if compression is successful, writes the block rounded up to the nearest 4KB.
The alternative zlib compression works a little differently: it will gather more data and compress enough to fill a 32KB block on disk. This is more CPU intensive but generally results in better compression ratios (independent of the inherent differences between snappy and zlib).
—Michael Cahill
This approach is great for performance. But compression still has overhead and can vary in effectiveness. What this means for users is two-fold:
- Not all data sets compress equally, it depends on the data format itself.
- Data compression is temporal. One day being better than another depending on the specific workload.
One approach is to take a mongodump of the dataset in question then mongorestore that data to a compressed WiredTiger database and measure the difference. This gives a rough measurement of what one can expect the compression ratio to be. That said, as soon as the new compressed database starts taking load, that compression ratio may vary. Probably not by a massive margin however.
It should be noted there are some tricky bits to consider when running a database using compression. Because WiredTiger compresses each page before it hits the disk the memory region is uncompressed. This means that highly compressed data will have a large ratio between its footprint on disk and the cache that serves it. Poorly compressed data the opposite. The effect may be the database becomes slow. It will be hard to know that the problem is the caching pattern has changed because the compression properties of the underlaying data have changed. Keeping good time series data on the cache utilization, and periodically checking the compression of the data by hand may help the DBA understand these patterns better.
For instance, note the different compression ratios of various datasets:
Take Aways
- MongoDB 3.0 has a new storage engine API, and is delivered with the optional WiredTiger engine.
- MongoDB 3.0 with WiredTiger is much faster than MMAPv1 mostly because of increased concurrency.
- MongoDB 3.0 with WiredTiger is much faster than MMAPv1 even when compressing the data.
Lastly, remember, MongoDB 3.0 is a new piece of software. Test before moving production workloads to it. TEST TEST TEST.
If you would like to test MongoDB 3.0 with WiredTiger, ObjectRocket has it as generally available and it's simple and quick to setup. As with anything ObjectRocket, there are a team of DBAs and Developers to help you with your projects. Don't be shy hitting them up at support@objectrocket.com with questions or email me directly.
Note: test configuration and details documented here.