This project aims at creating a simple efficient building block for "Big Data" libraries, applications and frameworks; thing that can be used as an in-memory, bounded queue with opaque values (sequence of JDK primitive values): insertions at tail, removal from head, single entry peeks), and that has minimal garbage collection overhead. Insertions and removals are as individual entries, which are sub-sequences of the full buffer.
GC overhead minimization is achieved by use of direct ByteBuffer
s (memory allocated outside of GC-prone heap); and bounded nature by only supporting storage of simple primitive value (byte
, `long') sequences where size is explicitly known.
Conceptually memory buffers are just simple circular buffers (ring buffers) that hold a sequence of primitive values, bit like arrays, but in a way that allows dynamic automatic resizings of the underlying storage. Library supports efficient reusing and sharing of underlying segments for sets of buffers, although for many use cases a single buffer suffices.
Buffers vary in two dimensions:
- Type of primitive value contained: currently
byte
andlong
variants are implemente, but others (likeint
orchar
) will be easy to add as needed - Whether sequences are "chunky" -- sequences consists of 'chunks' created by distinct
appendEntry()
calls (and retrieved in exactly same sized chunks withgetNextEntry()
) -- or "streamy", meaning that values are coalesced and form a logical stream (so multipleappendEntry()
calls may be coalesced into just one entry returned bygetNextEntry()
).
Since Java has no support for "generic primitives", there are separate classes for all combinations. This means that there are currently 4 flavors of buffers:
- for
byte
(usingMemBuffersForBytes
) ChunkyBytesMemBuffer
StreamyBytesMemBuffer
- for
long
(usingMemBuffersForLongs
) ChunkyLongsMemBuffer
StreamyLongsMemBuffer
Another thing that can vary is the way underlying segments are allocated; default is to use native ("direct") ByteBuffer
s. But more on this later on.
Standard Apache 2.0 license.
Although having individual buffers is useful as is, this is just the beginning.
Conceptually library supports "buffer groups", sets of similary-valued buffer instances owned by a single factory (like MemBuffersForBytes
) that share same segment allocator (com.fasterxml.util.membuf.SegmentAllocator
).
This makes it possible to share set of reusable underlying ByteBuffer
instances for buffers in the same group.
This ability to share underlying segments between buffers, with strict memory bounds makes it possible to use library as basic buffer manager; for example to buffer input and/or output of a web server (byte-based "streamy" buffers), or as simplistic event queues (usually using "chunky" buffers).
To have multiple buffer groups simply construct multiple factory instances.
All pieces are designed to be used by multiple threads (often just 2, producer/consumer), so all access is properly synchronized.
In addition, locking is done using buffer instances, so it may occasionally make sense to synchronize on buffer instance since this allows you to create atomic sequences of operations, like so:
MemBuffersForBytes factory = new MemBuffersForBytes(...);
ChunkyBytesMemBuffer buffer = factory.createChunkyBuffer(...);
synchronized (buffer) {
// read latest, add right back:
byte[] msg = buffer.getNextEntry();
buffer.appendEntry(msg);
}
or similarly if you need to read a sequence of entries as atomic unit.
Project has been used by multiple production systems (by multiple companies) since 2012, and by now has proven stable and performant for expected use cases. As such it is considered production ready: the official 1.0 version was released in October 2013.
The first accessible project that uses it is Arecibo, a metrics collection, aggregation and visualization.
Companies that use this library for production systems include:
- Mode Media (nee Glam Media)
- Salesforce
To use with Maven, add:
<dependency>
<groupId>com.fasterxml.util</groupId>
<artifactId>low-gc-membuffers</artifactId>
<version>1.1.1</version>
</dependency>
For downloadables, javadocs check out Wiki.
Exact factory to use depends on value type: here we assume you are looking
for byte-based buffers. If so, you will use MemBuffersForBytes
.
This object can be viewed as container and factory of actual buffers
(ChunkyBytesMemBuffer
or StreamyBytesMemBuffer
).
To construct one, you need to specify amount of memory to use, as well as how memory should be sliced: so, for example:
MemBuffersForBytes factory = new MemBuffersForBytes(30 * 1024, 2, 11);
would create instance that allocates at least 2 (and at most 11) segments (which wrap direct ByteBuffer
instances) with size of 30 kB: that is, has memory usage between 60 and 330 kilobytes.
The segments are then used by actual buffer instances (more on this in a bit)
So how do you choose parameters? Smaller the segments, more granular is memory allocation, which can mean more efficient memory use (since overhead is bounded to at most 1 segment-full per active buffer). But it also increases number of segment instances, possibly increasing fragmentation and adding overhead.
Note that you can create multiple instances of MemBuffers[Type]
factories, if you want to have more control over how pool of segments is allocated amongst individual buffers.
By default segments are allocated as ByteBuffer
s (or typed sub-types for long
s and so on). But this behavior can be changed by passing alternate
SegmentAllocator
instances.
For example, if you instead wanted to use in-heap segments stored as basic
byte arrays (byte[]
), you could do this by:
MemBuffersForBytes factory = new MemBuffersForBytes(
ArrayBytesSegment.allocator(30 * 1024, 2, 11));
or to use non-direct ByteBuffer
s:
MemBuffersForBytes factory = new MemBuffersForBytes(
ByteBufferBytesSegment.allocator(30 * 1024, 2, 11, false));
Note that SegmentAllocator
instances are implemented as inner classes of
matching segment type, that is as ArrayBytesSegment.Allocator
and
ByteBufferBytesSegment.Allocator
.
Also note that neither Allocator
s nor MemBuffers
keep track of underlying
segments. What this means it that buffers MUST be closed (explicitly, or indirectly by using wrappers) to make sure segments are released for reuse.
Actual buffers are then allocated using
ChunkyBytesMemBuffer items = bufs.createChunkyBuffer(2, 5);
which would indicate that this buffer will hold on to at least 2 segments (i.e. about 60kB raw storage) and use at most 5 (so max usage of 150kB). Due to circular buffer style of allocation, at least 'segments - 1' amount of memory will be available for actual queue (i.e. guaranteed space of 120kB; that is, up to one segment may be temporarily unavailable depending on pattern of append/remove operations.
To append entries, you use:
byte[] dataEntry = ...; // serialize from, say, JSON
items.appendEntry(dataEntry);
or, if you don't want an exception if there is no more room:
if (!items.tryAppendEntry(dataEntry)) {
// recover? Drop entry? Log?
}
and to pop entries:
byte[] next = items.getNextEntry(); // blocks if nothing available
// or:
next = items.getNextEntryIfAvailable();
if (next == null) { // nothing yet available
//...
}
// or:
next = items.getNextEntry(1000L); // block for at most 1 second before giving up
You '''always close buffers''' when you are done with them -- otherwise underlying segments may be leaked. This because buffers are only objects that keep track of segments; and nothing keeps track of MemBuffer
instances created -- this is intentional, as synchronization otherwise needed is very expensive from concurrency perspective.
Note that version 0.9.1 allows use of MemBufferDecorator
instances, which makes it possible to build wrappers that can implement simple auto-closing of buffers.
Finally, you can also obtain various statistics of buffer instances:
int entries = items.getEntryCount(); // how many available for getting?
int segmentsInUse = items.getSegmentCount(); // nr of internal segments
long maxFree = items.getMaximumAvailableSpace(); // approximate free space
long payload = items.getTotalPayloadLength(); // how much used by data?
Check out Wiki for downloads, Javadocs etc.
Default (and currently only) buffer implementation uses direct ByteBuffer
s, and amount of memory that can be allocated is limited by JVM option -XX:MaxDirectMemorySize
, which by default has relatively low size of 64megs.
To increase this setting, add setting like:
-XX:MaxDirectMemorySize=512m
otherwise you are likely to hit an OutOfMemoryError when using larger buffers.
Here are some improvement ideas:
- "Slab" allocation (issue #14): allow initial allocation of a longer off-heap memory segment, with size of
N
segments: this "slab" will be fixed and NOT dynamically allocated or freed; segments will be sub-allocated as needed.- Main benefit is reduced need for actually memory management (no per-operation
malloc
orfree
) - Adds fixed overhead: slab size needs to be balanced with costs
- Segments from slabs allocated before dynamic segments, as they do not incur additional allocation or memory usage cost (due to fixed default overhead)
- Main benefit is reduced need for actually memory management (no per-operation
- Expose streamy byte buffers as
InputStream
(issue #19).- Would need to choose what happens with end-of-input: snapshot (expose current and as EOF) vs blocking (works like pipe)