@Experimental public final class ApproximateDistinct extends java.lang.Object
PTransform
s for computing the approximate number of distinct elements in a stream.
This class relies on the HyperLogLog algorithm, and more precisely HyperLogLog+, the improved version of Google.
The implementation comes from Addthis'
Stream-lib library.
The original paper of the HyperLogLog is available here.
A paper from the same authors to have a clearer view of the algorithm is available here.
Google's HyperLogLog+ version is detailed in this paper.
Two parameters can be tuned in order to control the computation's accuracy:
p
1.1 / sqrt(2^p)
. The value
should be of at least 4 to guarantee a minimal accuracy. 12
for a relative error of around 2%
.
sp
sp
should be greater than p
, but lower than 32. sp = 0
). One should use it if
the cardinality may be less than 12000
.
There are 2 ways of using this class:
PTransform
s that return PCollection<Long>
corresponding to the
estimate number of distinct elements in the input PCollection
of objects or for
each key in a PCollection
of KV
s.
ApproximateDistinct.ApproximateDistinctFn
CombineFn
that is exposed in order to make
advanced processing involving the HyperLogLogPlus
structure which resumes the
stream.
PCollection<Integer> input = ...;
PCollection<Long> hllSketch = input.apply(ApproximateDistinct.<Integer>globally());
PCollection<Integer, String> input = ...;
PCollection<Integer, Long> hllSketches = input.apply(ApproximateDistinct
.<Integer, String>perKey());
One can tune the precision and sparse precision parameters in order to control the accuracy
and the memory. The tuning works exactly the same for globally()
and perKey()
.
int precision = 15;
int sparsePrecision = 25;
PCollection<Double> input = ...;
PCollection<Long> hllSketch = input.apply(ApproximateDistinct
.<Double>globally()
.withPrecision(precision)
.withSparsePrecision(sparsePrecision));
ApproximateDistinct.ApproximateDistinctFn
CombineFnThe CombineFn does the same thing as the transform but it can be used in cases where you want
to manipulate the HyperLogLogPlus
sketch, for example if you want to store it in a
database to have a backup. It can also be used in stateful processing or in CombineFns.ComposedCombineFn
.
This example is not really interesting but show how you can properly create an ApproximateDistinct.ApproximateDistinctFn
. One must always specify a coder using the ApproximateDistinct.ApproximateDistinctFn.create(Coder)
method.
PCollection<Integer> input = ...;
PCollection<HyperLogLogPlus> output = input.apply(Combine.globally(ApproximateDistinctFn
.<Integer>create(BigEndianIntegerCoder.of()));
Combine.CombineFn
in a stateful ParDo
One may want to use the ApproximateDistinct.ApproximateDistinctFn
in a stateful ParDo in order to make
some processing depending on the current cardinality of the stream.
For more information about stateful processing see the blog spot on this topic here.
Here is an example of DoFn
using an ApproximateDistinct.ApproximateDistinctFn
as a CombiningState
:
class StatefulCardinality<V> extends DoFn<V, OutputT> {
@StateId("hyperloglog")
private final StateSpec<CombiningState<V, HyperLogLogPlus, HyperLogLogPlus>>
indexSpec;
public StatefulCardinality(ApproximateDistinctFn<V> fn) {
indexSpec = StateSpecs.combining(fn);
}
@ProcessElement
public void processElement(
ProcessContext context,
@StateId("hllSketch")
CombiningState<V, HyperLogLogPlus, HyperLogLogPlus> hllSketch) {
long current = MoreObjects.firstNonNull(hllSketch.getAccum().cardinality(), 0L);
hllSketch.add(context.element());
context.output(...);
}
}
Then the DoFn
can be called like this:
PCollection<V> input = ...;
ApproximateDistinctFn<V> myFn = ApproximateDistinctFn.create(input.getCoder());
PCollection<V> = input.apply(ParDo.of(new StatefulCardinality<>(myFn)));
RetrieveCardinality
utility classOne may want to retrieve the cardinality as a long after making some advanced processing using
the HyperLogLogPlus
structure.
The RetrieveCardinality
utility class provides an easy way to do so:
PCollection<MyObject> input = ...;
PCollection<HyperLogLogPlus> hll = input.apply(Combine.globally(ApproximateDistinctFn
.<MyObject>create(new MyObjectCoder())
.withSparseRepresentation(20)));
// Some advanced processing
PCollection<SomeObject> advancedResult = hll.apply(...);
PCollection<Long> cardinality = hll.apply(ApproximateDistinct.RetrieveCardinality.globally());
Warning: this class is experimental. Its API is subject to change in future versions of
Beam. For example, it may be merged with the ApproximateUnique
transform.
Modifier and Type | Class and Description |
---|---|
static class |
ApproximateDistinct.ApproximateDistinctFn<InputT>
Implements the
Combine.CombineFn of ApproximateDistinct transforms. |
static class |
ApproximateDistinct.GloballyDistinct<InputT>
Implementation of
globally() . |
static class |
ApproximateDistinct.HyperLogLogPlusCoder
Coder for
HyperLogLogPlus class. |
static class |
ApproximateDistinct.PerKeyDistinct<K,V>
Implementation of
perKey() . |
Constructor and Description |
---|
ApproximateDistinct() |
Modifier and Type | Method and Description |
---|---|
static <InputT> ApproximateDistinct.GloballyDistinct<InputT> |
globally()
Computes the approximate number of distinct elements in the input
PCollection<InputT>
and returns a PCollection<Long> . |
static <K,V> ApproximateDistinct.PerKeyDistinct<K,V> |
perKey()
Like
globally() but per key, i.e computes the approximate number of distinct values per
key in a PCollection<KV<K, V>> and returns PCollection<KV<K, Long>> . |
static long |
precisionForRelativeError(double relativeError)
Computes the precision based on the desired relative error.
|
static double |
relativeErrorForPrecision(int p) |
public static <InputT> ApproximateDistinct.GloballyDistinct<InputT> globally()
PCollection<InputT>
and returns a PCollection<Long>
.InputT
- the type of the elements in the input PCollection
public static <K,V> ApproximateDistinct.PerKeyDistinct<K,V> perKey()
globally()
but per key, i.e computes the approximate number of distinct values per
key in a PCollection<KV<K, V>>
and returns PCollection<KV<K, Long>>
.K
- type of the keys mapping the elementsV
- type of the values being combined per keypublic static long precisionForRelativeError(double relativeError)
According to the paper, the mean squared error is bounded by the following formula:
b(m) / sqrt(m) Where m is the number of buckets used (p = log2(m)
) andb(m) < 1.106
form > 16 (and p > 4)
.
PCollection
, the lower the variation will
be. {1,2,3,4,5,6}
will get closer to 1/6
.relativeError
- the mean squared error should be in the interval ]0,1]public static double relativeErrorForPrecision(int p)
p
- the precision i.e. the number of bits used for indexing the buckets