Histogram aggregation
editHistogram aggregation
editA multi-bucket values source based aggregation that can be applied on numeric values or numeric range values extracted
from the documents. It dynamically builds fixed size (a.k.a. interval) buckets over the values. For example, if the
documents have a field that holds a price (numeric), we can configure this aggregation to dynamically build buckets with
interval 5
(in case of price it may represent $5). When the aggregation executes, the price field of every document
will be evaluated and will be rounded down to its closest bucket - for example, if the price is 32
and the bucket size
is 5
then the rounding will yield 30
and thus the document will "fall" into the bucket that is associated with the
key 30
.
To make this more formal, here is the rounding function that is used:
bucket_key = Math.floor((value - offset) / interval) * interval + offset
For range values, a document can fall into multiple buckets. The first bucket is computed from the lower bound of the range in the same way as a bucket for a single value is computed. The final bucket is computed in the same way from the upper bound of the range, and the range is counted in all buckets in between and including those two.
The interval
must be a positive decimal, while the offset
must be a decimal in [0, interval)
(a decimal greater than or equal to 0
and less than interval
)
The following snippet "buckets" the products based on their price
by interval of 50
:
resp = client.search( index="sales", size="0", aggs={ "prices": { "histogram": { "field": "price", "interval": 50 } } }, ) print(resp)
response = client.search( index: 'sales', size: 0, body: { aggregations: { prices: { histogram: { field: 'price', interval: 50 } } } } ) puts response
const response = await client.search({ index: "sales", size: 0, aggs: { prices: { histogram: { field: "price", interval: 50, }, }, }, }); console.log(response);
POST /sales/_search?size=0 { "aggs": { "prices": { "histogram": { "field": "price", "interval": 50 } } } }
And the following may be the response:
{ ... "aggregations": { "prices": { "buckets": [ { "key": 0.0, "doc_count": 1 }, { "key": 50.0, "doc_count": 1 }, { "key": 100.0, "doc_count": 0 }, { "key": 150.0, "doc_count": 2 }, { "key": 200.0, "doc_count": 3 } ] } } }
Minimum document count
editThe response above show that no documents has a price that falls within the range of [100, 150)
. By default the
response will fill gaps in the histogram with empty buckets. It is possible to change that and request buckets with
a higher minimum count thanks to the min_doc_count
setting:
resp = client.search( index="sales", size="0", aggs={ "prices": { "histogram": { "field": "price", "interval": 50, "min_doc_count": 1 } } }, ) print(resp)
response = client.search( index: 'sales', size: 0, body: { aggregations: { prices: { histogram: { field: 'price', interval: 50, min_doc_count: 1 } } } } ) puts response
const response = await client.search({ index: "sales", size: 0, aggs: { prices: { histogram: { field: "price", interval: 50, min_doc_count: 1, }, }, }, }); console.log(response);
POST /sales/_search?size=0 { "aggs": { "prices": { "histogram": { "field": "price", "interval": 50, "min_doc_count": 1 } } } }
Response:
{ ... "aggregations": { "prices": { "buckets": [ { "key": 0.0, "doc_count": 1 }, { "key": 50.0, "doc_count": 1 }, { "key": 150.0, "doc_count": 2 }, { "key": 200.0, "doc_count": 3 } ] } } }
By default the histogram
returns all the buckets within the range of the data itself, that is, the documents with
the smallest values (on which with histogram) will determine the min bucket (the bucket with the smallest key) and the
documents with the highest values will determine the max bucket (the bucket with the highest key). Often, when
requesting empty buckets, this causes a confusion, specifically, when the data is also filtered.
To understand why, let’s look at an example:
Lets say the you’re filtering your request to get all docs with values between 0
and 500
, in addition you’d like
to slice the data per price using a histogram with an interval of 50
. You also specify "min_doc_count" : 0
as you’d
like to get all buckets even the empty ones. If it happens that all products (documents) have prices higher than 100
,
the first bucket you’ll get will be the one with 100
as its key. This is confusing, as many times, you’d also like
to get those buckets between 0 - 100
.
With extended_bounds
setting, you now can "force" the histogram aggregation to start building buckets on a specific
min
value and also keep on building buckets up to a max
value (even if there are no documents anymore). Using
extended_bounds
only makes sense when min_doc_count
is 0 (the empty buckets will never be returned if min_doc_count
is greater than 0).
Note that (as the name suggest) extended_bounds
is not filtering buckets. Meaning, if the extended_bounds.min
is higher
than the values extracted from the documents, the documents will still dictate what the first bucket will be (and the
same goes for the extended_bounds.max
and the last bucket). For filtering buckets, one should nest the histogram aggregation
under a range filter
aggregation with the appropriate from
/to
settings.
Example:
resp = client.search( index="sales", size="0", query={ "constant_score": { "filter": { "range": { "price": { "lte": "500" } } } } }, aggs={ "prices": { "histogram": { "field": "price", "interval": 50, "extended_bounds": { "min": 0, "max": 500 } } } }, ) print(resp)
const response = await client.search({ index: "sales", size: 0, query: { constant_score: { filter: { range: { price: { lte: "500", }, }, }, }, }, aggs: { prices: { histogram: { field: "price", interval: 50, extended_bounds: { min: 0, max: 500, }, }, }, }, }); console.log(response);
POST /sales/_search?size=0 { "query": { "constant_score": { "filter": { "range": { "price": { "lte": "500" } } } } }, "aggs": { "prices": { "histogram": { "field": "price", "interval": 50, "extended_bounds": { "min": 0, "max": 500 } } } } }
When aggregating ranges, buckets are based on the values of the returned documents. This means the response may include buckets outside of a query’s range. For example, if your query looks for values greater than 100, and you have a range covering 50 to 150, and an interval of 50, that document will land in 3 buckets - 50, 100, and 150. In general, it’s best to think of the query and aggregation steps as independent - the query selects a set of documents, and then the aggregation buckets those documents without regard to how they were selected. See note on bucketing range fields for more information and an example.
The hard_bounds
is a counterpart of extended_bounds
and can limit the range of buckets in the histogram. It is
particularly useful in the case of open data ranges that can result in a very large number of buckets.
Example:
resp = client.search( index="sales", size="0", query={ "constant_score": { "filter": { "range": { "price": { "lte": "500" } } } } }, aggs={ "prices": { "histogram": { "field": "price", "interval": 50, "hard_bounds": { "min": 100, "max": 200 } } } }, ) print(resp)
const response = await client.search({ index: "sales", size: 0, query: { constant_score: { filter: { range: { price: { lte: "500", }, }, }, }, }, aggs: { prices: { histogram: { field: "price", interval: 50, hard_bounds: { min: 100, max: 200, }, }, }, }, }); console.log(response);
POST /sales/_search?size=0 { "query": { "constant_score": { "filter": { "range": { "price": { "lte": "500" } } } } }, "aggs": { "prices": { "histogram": { "field": "price", "interval": 50, "hard_bounds": { "min": 100, "max": 200 } } } } }
In this example even though the range specified in the query is up to 500, the histogram will only have 2 buckets starting at 100 and 150. All other buckets will be omitted even if documents that should go to this buckets are present in the results.
Order
editBy default the returned buckets are sorted by their key
ascending, though the order behaviour can be controlled using
the order
setting. Supports the same order
functionality as the Terms Aggregation
.
Offset
editBy default the bucket keys start with 0 and then continue in even spaced steps
of interval
, e.g. if the interval is 10
, the first three buckets (assuming
there is data inside them) will be [0, 10)
, [10, 20)
, [20, 30)
. The bucket
boundaries can be shifted by using the offset
option.
This can be best illustrated with an example. If there are 10 documents with values ranging from 5 to 14, using interval 10
will result in
two buckets with 5 documents each. If an additional offset 5
is used, there will be only one single bucket [5, 15)
containing all the 10
documents.
Response Format
editBy default, the buckets are returned as an ordered array. It is also possible to request the response as a hash instead keyed by the buckets keys:
resp = client.search( index="sales", size="0", aggs={ "prices": { "histogram": { "field": "price", "interval": 50, "keyed": True } } }, ) print(resp)
response = client.search( index: 'sales', size: 0, body: { aggregations: { prices: { histogram: { field: 'price', interval: 50, keyed: true } } } } ) puts response
const response = await client.search({ index: "sales", size: 0, aggs: { prices: { histogram: { field: "price", interval: 50, keyed: true, }, }, }, }); console.log(response);
POST /sales/_search?size=0 { "aggs": { "prices": { "histogram": { "field": "price", "interval": 50, "keyed": true } } } }
Response:
{ ... "aggregations": { "prices": { "buckets": { "0.0": { "key": 0.0, "doc_count": 1 }, "50.0": { "key": 50.0, "doc_count": 1 }, "100.0": { "key": 100.0, "doc_count": 0 }, "150.0": { "key": 150.0, "doc_count": 2 }, "200.0": { "key": 200.0, "doc_count": 3 } } } } }
Missing value
editThe missing
parameter defines how documents that are missing a value should be treated.
By default they will be ignored but it is also possible to treat them as if they
had a value.
resp = client.search( index="sales", size="0", aggs={ "quantity": { "histogram": { "field": "quantity", "interval": 10, "missing": 0 } } }, ) print(resp)
response = client.search( index: 'sales', size: 0, body: { aggregations: { quantity: { histogram: { field: 'quantity', interval: 10, missing: 0 } } } } ) puts response
const response = await client.search({ index: "sales", size: 0, aggs: { quantity: { histogram: { field: "quantity", interval: 10, missing: 0, }, }, }, }); console.log(response);
Histogram fields
editRunning a histogram aggregation over histogram fields computes the total number of counts for each interval.
For example, executing a histogram aggregation against the following index that stores pre-aggregated histograms with latency metrics (in milliseconds) for different networks:
resp = client.indices.create( index="metrics_index", mappings={ "properties": { "network": { "properties": { "name": { "type": "keyword" } } }, "latency_histo": { "type": "histogram" } } }, ) print(resp) resp1 = client.index( index="metrics_index", id="1", refresh=True, document={ "network.name": "net-1", "latency_histo": { "values": [ 1, 3, 8, 12, 15 ], "counts": [ 3, 7, 23, 12, 6 ] } }, ) print(resp1) resp2 = client.index( index="metrics_index", id="2", refresh=True, document={ "network.name": "net-2", "latency_histo": { "values": [ 1, 6, 8, 12, 14 ], "counts": [ 8, 17, 8, 7, 6 ] } }, ) print(resp2) resp3 = client.search( index="metrics_index", size="0", aggs={ "latency_buckets": { "histogram": { "field": "latency_histo", "interval": 5 } } }, ) print(resp3)
response = client.indices.create( index: 'metrics_index', body: { mappings: { properties: { network: { properties: { name: { type: 'keyword' } } }, latency_histo: { type: 'histogram' } } } } ) puts response response = client.index( index: 'metrics_index', id: 1, refresh: true, body: { 'network.name' => 'net-1', latency_histo: { values: [ 1, 3, 8, 12, 15 ], counts: [ 3, 7, 23, 12, 6 ] } } ) puts response response = client.index( index: 'metrics_index', id: 2, refresh: true, body: { 'network.name' => 'net-2', latency_histo: { values: [ 1, 6, 8, 12, 14 ], counts: [ 8, 17, 8, 7, 6 ] } } ) puts response response = client.search( index: 'metrics_index', size: 0, body: { aggregations: { latency_buckets: { histogram: { field: 'latency_histo', interval: 5 } } } } ) puts response
const response = await client.indices.create({ index: "metrics_index", mappings: { properties: { network: { properties: { name: { type: "keyword", }, }, }, latency_histo: { type: "histogram", }, }, }, }); console.log(response); const response1 = await client.index({ index: "metrics_index", id: 1, refresh: "true", document: { "network.name": "net-1", latency_histo: { values: [1, 3, 8, 12, 15], counts: [3, 7, 23, 12, 6], }, }, }); console.log(response1); const response2 = await client.index({ index: "metrics_index", id: 2, refresh: "true", document: { "network.name": "net-2", latency_histo: { values: [1, 6, 8, 12, 14], counts: [8, 17, 8, 7, 6], }, }, }); console.log(response2); const response3 = await client.search({ index: "metrics_index", size: 0, aggs: { latency_buckets: { histogram: { field: "latency_histo", interval: 5, }, }, }, }); console.log(response3);
PUT metrics_index { "mappings": { "properties": { "network": { "properties": { "name": { "type": "keyword" } } }, "latency_histo": { "type": "histogram" } } } } PUT metrics_index/_doc/1?refresh { "network.name" : "net-1", "latency_histo" : { "values" : [1, 3, 8, 12, 15], "counts" : [3, 7, 23, 12, 6] } } PUT metrics_index/_doc/2?refresh { "network.name" : "net-2", "latency_histo" : { "values" : [1, 6, 8, 12, 14], "counts" : [8, 17, 8, 7, 6] } } POST /metrics_index/_search?size=0 { "aggs": { "latency_buckets": { "histogram": { "field": "latency_histo", "interval": 5 } } } }
The histogram
aggregation will sum the counts of each interval computed based on the values
and
return the following output:
{ ... "aggregations": { "latency_buckets": { "buckets": [ { "key": 0.0, "doc_count": 18 }, { "key": 5.0, "doc_count": 48 }, { "key": 10.0, "doc_count": 25 }, { "key": 15.0, "doc_count": 6 } ] } } }
Histogram aggregation is a bucket aggregation, which partitions documents into buckets rather than calculating metrics over fields like metrics aggregations do. Each bucket represents a collection of documents which sub-aggregations can run on. On the other hand, a histogram field is a pre-aggregated field representing multiple values inside a single field: buckets of numerical data and a count of items/documents for each bucket. This mismatch between the histogram aggregations expected input (expecting raw documents) and the histogram field (that provides summary information) limits the outcome of the aggregation to only the doc counts for each bucket.
Consequently, when executing a histogram aggregation over a histogram field, no sub-aggregations are allowed.
Also, when running histogram aggregation over histogram field the missing
parameter is not supported.