Time series data stream (TSDS)
editTime series data stream (TSDS)
editA time series data stream (TSDS) models timestamped metrics data as one or more time series.
You can use a TSDS to store metrics data more efficiently. In our benchmarks, metrics data stored in a TSDS used 70% less disk space than a regular data stream. The exact impact will vary per data set.
When to use a TSDS
editBoth a regular data stream and a TSDS can store timestamped
metrics data. Only use a TSDS if you typically add metrics data to Elasticsearch in near
real-time and @timestamp
order.
A TSDS is only intended for metrics data. For other timestamped data, such as logs or traces, use a logs data stream or regular data stream.
Differences from a regular data stream
editA TSDS works like a regular data stream with some key differences:
-
The matching index template for a TSDS requires a
data_stream
object with theindex.mode: time_series
option. This option enables most TSDS-related functionality. -
In addition to a
@timestamp
, each document in a TSDS must contain one or more dimension fields. The matching index template for a TSDS must contain mappings for at least onekeyword
dimension.TSDS documents also typically contain one or more metric fields.
-
Elasticsearch generates a hidden
_tsid
metadata field for each document in a TSDS. - A TSDS uses time-bound backing indices to store data from the same time period in the same backing index.
-
The matching index template for a TSDS must contain the
index.routing_path
index setting. A TSDS uses this setting to perform dimension-based routing. -
A TSDS uses internal index sorting to order
shard segments by
_tsid
and@timestamp
. -
TSDS documents only support auto-generated document
_id
values. For TSDS documents, the document_id
is a hash of the document’s dimensions and@timestamp
. A TSDS doesn’t support custom document_id
values. -
A TSDS uses synthetic
_source
, and as a result is subject to some restrictions and modifications applied to the_source
field.
A time series index can contain fields other than dimensions or metrics.
What is a time series?
editA time series is a sequence of observations for a specific entity. Together, these observations let you track changes to the entity over time. For example, a time series can track:
- CPU and disk usage for a computer
- The price of a stock
- Temperature and humidity readings from a weather sensor.
In a TSDS, each Elasticsearch document represents an observation, or data point, in a specific time series. Although a TSDS can contain multiple time series, a document can only belong to one time series. A time series can’t span multiple data streams.
Dimensions
editDimensions are field names and values that, in combination, identify a
document’s time series. In most cases, a dimension describes some aspect of the
entity you’re measuring. For example, documents related to the same weather
sensor may always have the same sensor_id
and location
values.
A TSDS document is uniquely identified by its time series and timestamp, both of
which are used to generate the document _id
. So, two documents with the same
dimensions and the same timestamp are considered to be duplicates. When you use
the _bulk
endpoint to add documents to a TSDS, a second document with the same
timestamp and dimensions overwrites the first. When you use the
PUT /<target>/_create/<_id>
format to add an individual document and a document
with the same _id
already exists, an error is generated.
You mark a field as a dimension using the boolean time_series_dimension
mapping parameter. The following field types support the time_series_dimension
parameter:
For a flattened field, use the time_series_dimensions
parameter to configure an array of fields as dimensions.
For details refer to flattened
.
Dimension definitions can be simplified through pass-through fields.
Metrics
editMetrics are fields that contain numeric measurements, as well as aggregations and/or downsampling values based off of those measurements. While not required, documents in a TSDS typically contain one or more metric fields.
Metrics differ from dimensions in that while dimensions generally remain constant, metrics are expected to change over time, even if rarely or slowly.
To mark a field as a metric, you must specify a metric type using the
time_series_metric
mapping parameter. The following field types support the
time_series_metric
parameter:
Accepted metric types vary based on the field type:
Valid values for time_series_metric
-
counter
-
A cumulative metric that only monotonically increases or resets to
0
(zero). For example, a count of errors or completed tasks.A counter field has additional semantic meaning, because it represents a cumulative counter. This works well with the
rate
aggregation, since a rate can be derived from a cumulative monotonically increasing counter. However a number of aggregations (for examplesum
) compute results that don’t make sense for a counter field, because of its cumulative nature.Only numeric and
aggregate_metric_double
fields support thecounter
metric type.
Due to the cumulative nature of counter fields, the following aggregations are supported and expected to provide meaningful results with the counter
field: rate
, histogram
, range
, min
, max
, top_metrics
and variable_width_histogram
. In order to prevent issues with existing integrations and custom dashboards, we also allow the following aggregations, even if the result might be meaningless on counters: avg
, box plot
, cardinality
, extended stats
, median absolute deviation
, percentile ranks
, percentiles
, stats
, sum
and value count
.
-
gauge
-
A metric that represents a single numeric that can arbitrarily increase or decrease. For example, a temperature or available disk space.
Only numeric and
aggregate_metric_double
fields support thegauge
metric type.
-
null
(Default) - Not a time series metric.
Time series mode
editThe matching index template for a TSDS must contain a data_stream
object with
the index_mode: time_series
option. This option ensures the TSDS creates
backing indices with an index.mode
setting of time_series
.
This setting enables most TSDS-related functionality in the backing indices.
If you convert an existing data stream to a TSDS, only backing indices created
after the conversion have an index.mode
of time_series
. You can’t
change the index.mode
of an existing backing index.
_tsid
metadata field
editWhen you add a document to a TSDS, Elasticsearch automatically generates a _tsid
metadata field for the document. The _tsid
is an object containing the
document’s dimensions. Documents in the same TSDS with the same _tsid
are part
of the same time series.
The _tsid
field is not queryable or updatable. You also can’t retrieve a
document’s _tsid
using a get document request. However, you can
use the _tsid
field in aggregations and retrieve the _tsid
value in searches
using the fields
parameter.
The format of the _tsid
field shouldn’t be relied upon. It may change
from version to version.
Time-bound indices
editIn a TSDS, each backing index, including the most recent backing index, has a
range of accepted @timestamp
values. This range is defined by the
index.time_series.start_time
and
index.time_series.end_time
index settings.
When you add a document to a TSDS, Elasticsearch adds the document to the appropriate
backing index based on its @timestamp
value. As a result, a TSDS can add
documents to any TSDS backing index that can receive writes. This applies even
if the index isn’t the most recent backing index.
Some ILM actions mark the source index as read-only, or expect the index
to not be actively written anymore in order to provide good performance. These actions are:
- Delete
- Downsample
- Force merge
- Read only
- Searchable snapshot
- Shrink
Index lifecycle management will not proceed with executing these actions until the upper time-bound
for accepting writes, represented by the index.time_series.end_time
index setting, has lapsed.
If no backing index can accept a document’s @timestamp
value, Elasticsearch rejects the
document.
Elasticsearch automatically configures index.time_series.start_time
and
index.time_series.end_time
settings as part of the index creation and rollover
process.
Look-ahead time
editUse the index.look_ahead_time
index setting to
configure how far into the future you can add documents to an index. When you
create a new write index for a TSDS, Elasticsearch calculates the index’s
index.time_series.end_time
value as:
now + index.look_ahead_time
At the time series poll interval (controlled via time_series.poll_interval
setting),
Elasticsearch checks if the write index has met the rollover criteria in its index
lifecycle policy. If not, Elasticsearch refreshes the now
value and updates the write
index’s index.time_series.end_time
to:
now + index.look_ahead_time + time_series.poll_interval
This process continues until the write index rolls over. When the index rolls
over, Elasticsearch sets a final index.time_series.end_time
value for the index. This
value borders the index.time_series.start_time
for the new write index. This
ensures the @timestamp
ranges for neighboring backing indices always border
but never overlap.
Look-back time
editUse the index.look_back_time
index setting to
configure how far in the past you can add documents to an index. When you
create a data stream for a TSDS, Elasticsearch calculates the index’s
index.time_series.start_time
value as:
now - index.look_back_time
This setting is only used when a data stream gets created and controls
the index.time_series.start_time
index setting of the first backing index.
Configuring this index setting can be useful to accept documents with @timestamp
field values that are older than 2 hours (the index.look_back_time
default).
Accepted time range for adding data
editA TSDS is designed to ingest current metrics data. When the TSDS is first created the initial backing index has:
-
an
index.time_series.start_time
value set tonow - index.look_back_time
-
an
index.time_series.end_time
value set tonow + index.look_ahead_time
Only data that falls inside that range can be indexed.
You can use the get data stream API to check the accepted time range for writing to any TSDS.
Dimension-based routing
editWithin each TSDS backing index, Elasticsearch uses the
index.routing_path
index setting to route documents
with the same dimensions to the same shards.
When you create the matching index template for a TSDS, you must specify one or
more dimensions in the index.routing_path
setting. Each document in a TSDS
must contain one or more dimensions that match the index.routing_path
setting.
The index.routing_path
setting accepts wildcard patterns (for example dim.*
)
and can dynamically match new fields. However, Elasticsearch will reject any mapping
updates that add scripted, runtime, or non-dimension fields that
match the index.routing_path
value.
Pass-through fields may be configured as dimension containers. In this case, their sub-fields get included to the routing path automatically.
TSDS documents don’t support a custom _routing
value. Similarly, you can’t
require a _routing
value in mappings for a TSDS.
Index sorting
editElasticsearch uses compression algorithms to compress repeated values. This compression works best when repeated values are stored near each other — in the same index, on the same shard, and side-by-side in the same shard segment.
Most time series data contains repeated values. Dimensions are repeated across documents in the same time series. The metric values of a time series may also change slowly over time.
Internally, each TSDS backing index uses index
sorting to order its shard segments by _tsid
and @timestamp
. This makes it
more likely that these repeated values are stored near each other for better
compression. A TSDS doesn’t support any
index.sort.*
index settings.
What’s next?
editNow that you know the basics, you’re ready to create a TSDS or convert an existing data stream to a TSDS.