Status: Mixed
Table of Contents
- MeterProvider
- Meter
- Attribute limits
- Exemplar
- MetricReader
- MetricExporter
- MetricProducer
- MetricFilter
- Defaults and configuration
- Numerical limits handling
- Compatibility requirements
- Concurrency requirements
- References
Users of OpenTelemetry need a way for instrumentation interactions with the OpenTelemetry API to actually produce telemetry. The OpenTelemetry SDK (henceforth referred to as the SDK) is an implementation of the OpenTelemetry API that provides users with this functionally.
All language implementations of OpenTelemetry MUST provide an SDK.
Status: Stable
A MeterProvider
MUST provide a way to allow a Resource to
be specified. If a Resource
is specified, it SHOULD be associated with all the
metrics produced by any Meter
from the MeterProvider
. The tracing SDK
specification has provided some
suggestions regarding how to implement this efficiently.
The SDK SHOULD allow the creation of multiple independent MeterProvider
s.
It SHOULD only be possible to create Meter
instances through a MeterProvider
(see API).
The MeterProvider
MUST implement the Get a Meter API.
The input provided by the user MUST be used to create
an InstrumentationScope
instance which
is stored on the created Meter
.
In the case where an invalid name
(null or empty string) is specified, a
working Meter MUST be returned as a fallback rather than returning null or
throwing an exception, its name
SHOULD keep the original invalid value, and a
message reporting that the specified value is invalid SHOULD be logged.
Status: Development - The MeterProvider
MUST
compute the relevant MeterConfig using the
configured MeterConfigurator, and create
a Meter
whose behavior conforms to that MeterConfig
.
Configuration (
i.e. MetricExporters, MetricReaders, Views,
and (Development) MeterConfigurator) MUST be
owned by the MeterProvider
. The configuration MAY be applied at the time
of MeterProvider
creation if appropriate.
The MeterProvider
MAY provide methods to update the configuration. If
configuration is updated (e.g., adding a MetricReader
), the updated
configuration MUST also apply to all already returned Meters
(i.e. it MUST NOT
matter whether a Meter
was obtained from the MeterProvider
before or after
the configuration change). Note: Implementation-wise, this could mean that
Meter
instances have a reference to their MeterProvider
and access
configuration only via this reference.
Status: Development
A MeterConfigurator
is a function which computes
the MeterConfig for a Meter.
The function MUST accept the following parameter:
meter_scope
: TheInstrumentationScope
of theMeter
.
The function MUST return the relevant MeterConfig
, or some signal indicating
that the default MeterConfig should be used. This signal MAY
be nil, null, empty, or an instance of the default MeterConfig
depending on
what is idiomatic in the language.
This function is called when a Meter
is first created, and for each
outstanding Meter
when a MeterProvider
's MeterConfigurator
is
updated (if updating is supported). Therefore, it is important that it returns
quickly.
MeterConfigurator
is modeled as a function to maximize flexibility.
However, implementations MAY provide shorthand or helper functions to
accommodate common use cases:
- Select one or more Meters by name, with exact match or pattern matching.
- Disable one or more specific Meters.
- Disable all Meters, and selectively enable one or more specific Meters.
This method provides a way for provider to do any cleanup required.
Shutdown
MUST be called only once for each MeterProvider
instance. After the
call to Shutdown
, subsequent attempts to get a Meter
are not allowed. SDKs
SHOULD return a valid no-op Meter for these calls, if possible.
Shutdown
SHOULD provide a way to let the caller know whether it succeeded,
failed or timed out.
Shutdown
SHOULD complete or abort within some timeout. Shutdown
MAY be
implemented as a blocking API or an asynchronous API which notifies the caller
via a callback or an event. OpenTelemetry SDK authors MAY
decide if they want to make the shutdown timeout configurable.
Shutdown
MUST be implemented at least by invoking Shutdown
on all registered
MetricReader and MetricExporter instances.
This method provides a way for provider to notify the registered
MetricReader instances that have an associated
Push Metric Exporter, so they can do as much
as they could to collect and send the metrics.
Note: Pull Metric Exporter can only send the
data when it is being asked by the scraper, so ForceFlush
would not make much
sense.
ForceFlush
MUST invoke ForceFlush
on all registered
MetricReader instances that implement ForceFlush
.
ForceFlush
SHOULD provide a way to let the caller know whether it succeeded,
failed or timed out. ForceFlush
SHOULD return some ERROR status if there
is an error condition; and if there is no error condition, it should return some
NO ERROR status, language implementations MAY decide how to model ERROR
and NO ERROR.
ForceFlush
SHOULD complete or abort within some timeout. ForceFlush
MAY be
implemented as a blocking API or an asynchronous API which notifies the caller
via a callback or an event. OpenTelemetry SDK authors MAY
decide if they want to make the flush timeout configurable.
A View
provides SDK users with the flexibility to customize the metrics that
are output by the SDK. Here are some examples when a View
might be needed:
- Customize which Instruments are to be processed/ignored. For example, an instrumented library can provide both temperature and humidity, but the application developer might only want temperature.
- Customize the aggregation - if the default aggregation associated with the Instrument does not meet the needs of the user. For example, an HTTP client library might expose HTTP client request duration as Histogram by default, but the application developer might only want the total count of outgoing requests.
- Customize which attribute(s) are to be reported on metrics. For example, an HTTP server library might expose HTTP verb (e.g. GET, POST) and HTTP status code (e.g. 200, 301, 404). The application developer might only care about HTTP status code (e.g. reporting the total count of HTTP requests for each HTTP status code). There could also be extreme scenarios in which the application developer does not need any attributes (e.g. just get the total count of all incoming requests).
The SDK MUST provide functionality for a user to create Views for a
MeterProvider
. This functionality MUST accept as inputs the Instrument
selection criteria and the resulting stream
configuration.
The SDK MUST provide the means to register Views with a MeterProvider
.
Instrument selection criteria are the predicates that determine if a View will be applied to an Instrument or not.
Criteria SHOULD be treated as additive. This means an Instrument has to match all the provided criteria for the View to be applied. For example, if the criteria are instrument name == "Foobar" and instrument type is Histogram, it will be treated as (instrument name == "Foobar") AND (instrument type is Histogram).
The SDK MUST accept the following criteria:
-
name
: The name of the Instrument(s) to match. Thisname
is evaluated to match an Instrument in the following manner.- If the value of
name
is*
, the criterion matches all Instruments. - If the value of
name
is exactly the same as an Instrument, then the criterion matches that instrument.
Additionally, the SDK MAY support wildcard pattern matching for the
name
criterion using the following characters.- A question mark (
?
): matches any single character - An asterisk (
*
): matches any number of any characters including none
If wildcard pattern matching is supported, the
name
criterion will match if the wildcard pattern is evaluated to match the Instrument name.If the SDK does not support wildcards in general, it MUST still recognize the special single asterisk (
*
) character as matching all Instruments.Users can provide a
name
, but it is up to their discretion. Therefore, the instrument selection criteria parameter needs to be structured to accept aname
, but MUST NOT obligate a user to provide one. - If the value of
-
type
: The type of Instruments to match. If the value oftype
is the same as an Instrument's type, then the criterion matches that Instrument.Users can provide a
type
, but it is up to their discretion. Therefore, the instrument selection criteria parameter needs to be structured to accept atype
, but MUST NOT obligate a user to provide one. -
unit
: If the value ofunit
is the same as an Instrument's unit, then the criterion matches that Instrument.Users can provide a
unit
, but it is up to their discretion. Therefore, the instrument selection criteria parameter needs to be structured to accept aunit
, but MUST NOT obligate a user to provide one. -
meter_name
: If the value ofmeter_name
is the same as the Meter that created an Instrument, then the criterion matches that Instrument.Users can provide a
meter_name
, but it is up to their discretion. Therefore, the instrument selection criteria parameter needs to be structured to accept ameter_name
, but MUST NOT obligate a user to provide one. -
meter_version
: If the value ofmeter_version
is the same version as the Meter that created an Instrument, then the criterion matches that Instrument.Users can provide a
meter_version
, but it is up to their discretion. Therefore, the instrument selection criteria parameter needs to be structured to accept ameter_version
, but MUST NOT obligate a user to provide one. -
meter_schema_url
: If the value ofmeter_schema_url
is the same schema URL as the Meter that created an Instrument, then the criterion matches that Instrument.Users can provide a
meter_schema_url
, but it is up to their discretion. Therefore, the instrument selection criteria parameter needs to be structured to accept ameter_schema_url
, but MUST NOT obligate a user to provide one.
The SDK MAY accept additional criteria. For example, a strongly typed language may support point type criterion (e.g. allow the users to select Instruments based on whether the underlying number is integral or rational). Users can provide these additional criteria the SDK accepts, but it is up to their discretion. Therefore, the instrument selection criteria can be structured to accept the criteria, but MUST NOT obligate a user to provide them.
Stream configuration are the parameters that define the metric
stream a MeterProvider
will
use to define telemetry pipelines.
The SDK MUST accept the following stream configuration parameters:
-
name
: The metric stream name that SHOULD be used.In order to avoid conflicts, if a
name
is provided the View SHOULD have an instrument selector that selects at most one instrument. If the Instrument selection criteria for a View with a stream configurationname
parameter can select more than one instrument (i.e. wildcards) the SDK MAY fail fast in accordance with initialization error handling principles.Users can provide a
name
, but it is up to their discretion. Therefore, the stream configuration parameter needs to be structured to accept aname
, but MUST NOT obligate a user to provide one. If the user does not provide aname
value, name from the Instrument the View matches MUST be used by default. -
description
: The metric stream description that SHOULD be used.Users can provide a
description
, but it is up to their discretion. Therefore, the stream configuration parameter needs to be structured to accept adescription
, but MUST NOT obligate a user to provide one. If the user does not provide adescription
value, the description from the Instrument a View matches MUST be used by default. -
attribute_keys
: This is, at a minimum, an allow-list of attribute keys for measurements captured in the metric stream. The allow-list contains attribute keys that identify the attributes that MUST be kept, and all other attributes MUST be ignored.Implementations MAY accept additional attribute filtering functionality for this parameter.
Users can provide
attribute_keys
, but it is up to their discretion. Therefore, the stream configuration parameter needs to be structured to acceptattribute_keys
, but MUST NOT obligate a user to provide them. If the user does not provide any value, the SDK SHOULD use theAttributes
advisory parameter configured on the instrument instead. If theAttributes
advisory parameter is absent, all attributes MUST be kept.Additionally, implementations SHOULD support configuring an exclude-list of attribute keys. The exclude-list contains attribute keys that identify the attributes that MUST be excluded, all other attributes MUST be kept. If an attribute key is both included and excluded, the SDK MAY fail fast in accordance with initialization error handling principles.
-
aggregation
: The name of an aggregation function to use in aggregating the metric stream data.Users can provide an
aggregation
, but it is up to their discretion. Therefore, the stream configuration parameter needs to be structured to accept anaggregation
, but MUST NOT obligate a user to provide one. If the user does not provide anaggregation
value, theMeterProvider
MUST apply a default aggregation configurable on the basis of instrument type according to the MetricReader instance. -
exemplar_reservoir
: A functional type that generates an exemplar reservoir aMeterProvider
will use when storing exemplars. This functional type needs to be a factory or callback similar to aggregation selection functionality which allows different reservoirs to be chosen by the aggregation.Users can provide an
exemplar_reservoir
, but it is up to their discretion. Therefore, the stream configuration parameter needs to be structured to accept anexemplar_reservoir
, but MUST NOT obligate a user to provide one. If the user does not provide anexemplar_reservoir
value, theMeterProvider
MUST apply a default exemplar reservoir. -
aggregation_cardinality_limit
: A positive integer value defining the maximum number of data points allowed to be emitted in a collection cycle by a single instrument. See cardinality limits, below.Users can provide an
aggregation_cardinality_limit
, but it is up to their discretion. Therefore, the stream configuration parameter needs to be structured to accept anaggregation_cardinality_limit
, but MUST NOT obligate a user to provide one. If the user does not provide anaggregation_cardinality_limit
value, theMeterProvider
MUST apply the default aggregation cardinality limit theMetricReader
is configured with.
The SDK SHOULD use the following logic to determine how to process Measurements made with an Instrument:
- Determine the
MeterProvider
which "owns" the Instrument. - If the
MeterProvider
has noView
registered, take the Instrument and apply the default Aggregation on the basis of instrument kind according to the MetricReader instance'saggregation
property. - If the
MeterProvider
has one or moreView
(s) registered:- If the Instrument could match the instrument selection criteria, for each
View:
- Try to apply the View's stream configuration independently of any other
Views registered for the same matching Instrument (i.e. Views are not
merged). This may result in conflicting metric identities
even if stream configurations specify non-overlapping properties (e.g.
one View setting
aggregation
and another View settingattribute_keys
, both leaving the streamname
as the default configured by the Instrument). If applying the View results in conflicting metric identities the implementation SHOULD apply the View and emit a warning. If it is not possible to apply the View without producing semantic errors (e.g. the View sets an asynchronous instrument to use the Explicit bucket histogram aggregation) the implementation SHOULD emit a warning and proceed as if the View did not exist.
- Try to apply the View's stream configuration independently of any other
Views registered for the same matching Instrument (i.e. Views are not
merged). This may result in conflicting metric identities
even if stream configurations specify non-overlapping properties (e.g.
one View setting
- If the Instrument could not match with any of the registered
View
(s), the SDK SHOULD enable the instrument using the default aggregation and temporality. Users can configure match-all Views using Drop aggregation to disable instruments by default.
- If the Instrument could match the instrument selection criteria, for each
View:
The following are examples of an SDK's functionality to create Views for a
MeterProvider
.
# Python
'''
+------------------+
| MeterProvider |
| Meter A |
| Counter X |
| Histogram Y |
| Meter B |
| Gauge Z |
+------------------+
'''
# metrics from X and Y (reported as Foo and Bar) will be exported
meter_provider
.add_view("X")
.add_view("Foo", instrument_name="Y")
.add_view(
"Bar",
instrument_name="Y",
aggregation=HistogramAggregation(buckets=[5.0, 10.0, 25.0, 50.0, 100.0]))
.add_metric_reader(PeriodicExportingMetricReader(ConsoleExporter()))
# all the metrics will be exported using the default configuration
meter_provider.add_metric_reader(PeriodicExportingMetricReader(ConsoleExporter()))
# all the metrics will be exported using the default configuration
meter_provider
.add_view("*") # a wildcard view that matches everything
.add_metric_reader(PeriodicExportingMetricReader(ConsoleExporter()))
# Counter X will be exported as cumulative sum
meter_provider
.add_view("X", aggregation=SumAggregation())
.add_metric_reader(PeriodicExportingMetricReader(ConsoleExporter()))
# Counter X will be exported as a delta sum and the default attributes
# Counter X, Histogram Y, and Gauge Z will be exported with 2 attributes (a and b)
# A warning will be emitted for conflicting metric identities on Counter X (as two Views matching that Instrument
# are configured with the same default name X) and streams from both views will be exported
meter_provider
.add_view("X", aggregation=SumAggregation())
.add_view("*", attribute_keys=["a", "b"]) # wildcard view matches everything, including X
.add_metric_reader(PeriodicExportingMetricReader(ConsoleExporter()),
temporality=lambda kind: Delta if kind in [Counter, AsyncCounter, Histogram] else Cumulative)
# Only Counter X will be exported, with the default configuration (match-all drop aggregation does not result in
# conflicting metric identities)
meter_provider
.add_view("X")
.add_view("*", aggregation=DropAggregation()) # a wildcard view to disable all instruments
.add_metric_reader(PeriodicExportingMetricReader(ConsoleExporter()))
An Aggregation
, as configured via the View,
informs the SDK on the ways and means to compute
Aggregated Metrics
from incoming Instrument Measurements.
Note: the term aggregation is used instead of aggregator. It is RECOMMENDED that implementors reserve the "aggregator" term for the future when the SDK allows custom aggregation implementations.
An Aggregation
specifies an operation
(i.e. decomposable aggregate function
like Sum, Histogram, Min, Max, Count)
and optional configuration parameter overrides.
The operation's default configuration parameter values will be used
unless overridden by optional configuration parameter overrides.
Note: Implementors MAY choose the best idiomatic practice for their language to represent the semantic of an Aggregation and optional configuration parameters.
e.g. The View specifies an Aggregation by string name (i.e. "ExplicitBucketHistogram").
# Use Histogram with custom boundaries
meter_provider
.add_view(
"X",
aggregation="ExplicitBucketHistogram",
aggregation_params={"Boundaries": [0, 10, 100]}
)
e.g. The View specifies an Aggregation by class/type instance.
// Use Histogram with custom boundaries
meterProviderBuilder
.AddView(
instrumentName: "X",
aggregation: new ExplicitBucketHistogramAggregation(
boundaries: new double[] { 0.0, 10.0, 100.0 }
)
);
The SDK MUST provide the following Aggregation
to support the
Metric Points in the
Metrics Data Model.
The SDK SHOULD provide the following Aggregation
:
The Drop Aggregation informs the SDK to ignore/drop all Instrument Measurements for this Aggregation.
This Aggregation does not have any configuration parameters.
The Default Aggregation informs the SDK to use the Instrument kind
to select
an aggregation and advisory
parameters to influence aggregation configuration
parameters (as noted in the "Selected Aggregation" column).
Instrument Kind | Selected Aggregation |
---|---|
Counter | Sum Aggregation |
Asynchronous Counter | Sum Aggregation |
UpDownCounter | Sum Aggregation |
Asynchronous UpDownCounter | Sum Aggregation |
Gauge | Last Value Aggregation |
Asynchronous Gauge | Last Value Aggregation |
Histogram | Explicit Bucket Histogram Aggregation, with the ExplicitBucketBoundaries advisory parameter if provided |
This Aggregation does not have any configuration parameters.
The Sum Aggregation informs the SDK to collect data for the Sum Metric Point.
The monotonicity of the aggregation is determined by the instrument type:
Instrument Kind | SumType |
---|---|
Counter | Monotonic |
UpDownCounter | Non-Monotonic |
Histogram | Monotonic |
Gauge | Non-Monotonic |
Asynchronous Gauge | Non-Monotonic |
Asynchronous Counter | Monotonic |
Asynchronous UpDownCounter | Non-Monotonic |
This Aggregation does not have any configuration parameters.
This Aggregation informs the SDK to collect:
- The arithmetic sum of
Measurement
values.
The Last Value Aggregation informs the SDK to collect data for the Gauge Metric Point.
This Aggregation does not have any configuration parameters.
This Aggregation informs the SDK to collect:
- The last
Measurement
. - The timestamp of the last
Measurement
.
All histogram Aggregations inform the SDK to collect:
- Count of
Measurement
values in population. - Arithmetic sum of
Measurement
values in population. This SHOULD NOT be collected when used with instruments that record negative measurements (e.g.UpDownCounter
orObservableGauge
). - Min (optional)
Measurement
value in population. - Max (optional)
Measurement
value in population.
The Explicit Bucket Histogram Aggregation informs the SDK to collect data for the Histogram Metric Point using a set of explicit boundary values for histogram bucketing.
This Aggregation honors the following configuration parameters:
Key | Value | Default Value | Description |
---|---|---|---|
Boundaries | double[] | [ 0, 5, 10, 25, 50, 75, 100, 250, 500, 750, 1000, 2500, 5000, 7500, 10000 ] | Array of increasing values representing explicit bucket boundary values. The Default Value represents the following buckets (heavily influenced by the default buckets of Prometheus clients, e.g. Java and Go): (-∞, 0], (0, 5.0], (5.0, 10.0], (10.0, 25.0], (25.0, 50.0], (50.0, 75.0], (75.0, 100.0], (100.0, 250.0], (250.0, 500.0], (500.0, 750.0], (750.0, 1000.0], (1000.0, 2500.0], (2500.0, 5000.0], (5000.0, 7500.0], (7500.0, 10000.0], (10000.0, +∞). SDKs SHOULD use the default value when boundaries are not explicitly provided, unless they have good reasons to use something different (e.g. for backward compatibility reasons in a stable SDK release). |
RecordMinMax | true, false | true | Whether to record min and max. |
Explicit buckets are stated in terms of their upper boundary. Buckets are exclusive of their lower boundary and inclusive of their upper bound (except at positive infinity). A measurement is defined to fall into the greatest-numbered bucket with boundary that is greater than or equal to the measurement.
The Base2 Exponential Histogram Aggregation informs the SDK to collect data
for the Exponential Histogram Metric
Point, which uses a base-2 exponential
formula to determine bucket boundaries and an integer scale
parameter to control resolution. Implementations adjust scale as necessary given
the data.
This Aggregation honors the following configuration parameters:
Key | Value | Default Value | Description |
---|---|---|---|
MaxSize | integer | 160 | Maximum number of buckets in each of the positive and negative ranges, not counting the special zero bucket. |
MaxScale | integer | 20 | Maximum scale factor. |
RecordMinMax | true, false | true | Whether to record min and max. |
The default of 160 buckets is selected to establish default support
for a high-resolution histogram able to cover a long-tail latency
distribution from 1ms to 100s with less than 5% relative error.
Because 160 can be factored into 10 * 2**K
, maximum contrast is
relatively simple to derive for scale K
:
Scale | Maximum data contrast at 10 * 2**K buckets |
---|---|
K+2 | 5.657 (2**(10/4)) |
K+1 | 32 (2**(10/2)) |
K | 1024 (2**10) |
K-1 | 1048576 (2**20) |
The following table shows how the ideal scale for 160 buckets is calculated as a function of the input range:
Input range | Contrast | Ideal Scale | Base | Relative error |
---|---|---|---|---|
1ms - 4ms | 4 | 6 | 1.010889 | 0.542% |
1ms - 20ms | 20 | 5 | 1.021897 | 1.083% |
1ms - 1s | 10**3 | 4 | 1.044274 | 2.166% |
1ms - 100s | 10**5 | 3 | 1.090508 | 4.329% |
1μs - 10s | 10**7 | 2 | 1.189207 | 8.643% |
Note that relative error is calculated as half of the bucket width
divided by the bucket midpoint, which is the same in every bucket.
Using the bucket from [1, base), we have (bucketWidth / 2) / bucketMidpoint = ((base - 1) / 2) / ((base + 1) / 2) = (base - 1) / (base + 1)
.
This Aggregation uses the notion of "ideal" scale. The ideal scale is either:
- The
MaxScale
(see configuration parameters), generally used for single-value histogram Aggregations where scale is not otherwise constrained. - The largest value of scale such that no more than the maximum number of buckets are needed to represent the full range of input data in either of the positive or negative ranges.
Implementations are REQUIRED to accept the entire normal range of IEEE floating point values (i.e., all values except for +Inf, -Inf and NaN values).
Implementations SHOULD NOT incorporate non-normal values (i.e., +Inf,
-Inf, and NaNs) into the sum
, min
, and max
fields, because these
values do not map into a valid bucket.
Implementations MAY round subnormal values away from zero to the nearest normal value.
The implementation MUST maintain reasonable minimum and maximum scale
parameters that the automatic scale parameter will not exceed. The maximum scale
is defined by the MaxScale
configuration parameter.
When the histogram contains not more than one value in either of the positive or negative ranges, the implementation SHOULD use the maximum scale.
Implementations SHOULD adjust the histogram scale as necessary to maintain the best resolution possible, within the constraint of maximum size (max number of buckets). Best resolution (highest scale) is achieved when the number of positive or negative range buckets exceeds half the maximum size, such that increasing scale by one would not be possible given the size constraint.
Callback functions MUST be invoked for the specific MetricReader
performing collection, such that observations made or produced by
executing callbacks only apply to the intended MetricReader
during
collection.
The implementation SHOULD disregard the use of asynchronous instrument APIs outside of registered callbacks.
The implementation SHOULD use a timeout to prevent indefinite callback execution.
The implementation MUST complete the execution of all callbacks for a given instrument before starting a subsequent round of collection.
The implementation SHOULD NOT produce aggregated metric data for a previously-observed attribute set which is not observed during a successful callback. See MetricReader for more details on the persistence of metrics across successive collections.
Status: Stable
SDKs SHOULD support being configured with a cardinality limit. The number of unique combinations of attributes is called cardinality. For a given metric, the cardinality limit is a hard limit on the number of Metric Points that can be collected during a collection cycle. Cardinality limit enforcement SHOULD occur after attribute filtering, if any. This ensures users can filter undesired attributes using views and prevent reaching the cardinality limit.
The cardinality limit for an aggregation is defined in one of three ways:
- A view with criteria matching the instrument an aggregation is
created for has an
aggregation_cardinality_limit
value defined for the stream, that value SHOULD be used. - If there is no matching view, but the
MetricReader
defines a default cardinality limit value based on the instrument an aggregation is created for, that value SHOULD be used. - If none of the previous values are defined, the default value of 2000 SHOULD be used.
An overflow attribute set is defined, containing a single attribute
otel.metric.overflow
having (boolean) value true
, which is used to report a
synthetic aggregation of the Measurements that could not
be independently aggregated because of the limit.
The SDK MUST create an Aggregator with the overflow attribute set prior to reaching the cardinality limit and use it to aggregate Measurements for which the correct Aggregator could not be created. The SDK MUST provide the guarantee that overflow would not happen if the maximum number of distinct, non-overflow attribute sets is less than or equal to the limit.
Aggregators for synchronous instruments with cumulative temporality MUST continue to export all attribute sets that were observed prior to the beginning of overflow. Measurements corresponding with attribute sets that were not observed prior to the overflow will be reflected in a single data point described by (only) the overflow attribute.
Aggregators of synchronous instruments with delta aggregation temporality MAY choose an arbitrary subset of attribute sets to output to maintain the stated cardinality limit.
Regardless of aggregation temporality, the SDK MUST ensure that every Measurement is reflected in exactly one Aggregator, which is either an Aggregator associated with the correct attribute set or an aggregator associated with the overflow attribute set.
Measurements MUST NOT be double-counted or dropped during an overflow.
Aggregators of asynchronous instruments SHOULD prefer the first-observed attributes in the callback when limiting cardinality, regardless of temporality.
Distinct meters MUST be treated as separate namespaces for the purposes of detecting duplicate instrument registrations.
Status: Development - Meter
MUST behave
according to the MeterConfig computed
during Meter creation. If the MeterProvider
supports
updating the MeterConfigurator, then upon update
the Meter
MUST be updated to behave according to the new MeterConfig
.
Status: Development
A MeterConfig
defines various configurable aspects of a Meter
's behavior.
It consists of the following parameters:
-
disabled
: A boolean indication of whether the Meter is enabled.If not explicitly set, the
disabled
parameter SHOULD default tofalse
( i.e.Meter
s are enabled by default).If a
Meter
is disabled, it MUST behave equivalently to No-op Meter.The value of
disabled
MUST be used to resolve whether an instrument is Enabled. See Instrument Enabled for details.
A duplicate instrument registration occurs when more than one Instrument of
the same name
is created for identical
Meters from the same MeterProvider but they have different identifying
fields.
Whenever this occurs, users still need to be able to make measurements with the duplicate instrument. This means that the Meter MUST return a functional instrument that can be expected to export data even if this will cause semantic error in the data model.
Additionally, users need to be informed about this error. Therefore, when a duplicate instrument registration occurs, and it is not corrected with a View, a warning SHOULD be emitted. The emitted warning SHOULD include information for the user on how to resolve the conflict, if possible.
- If the potential conflict involves multiple
description
properties, setting thedescription
through a configured View SHOULD avoid the warning. - If the potential conflict involves instruments that can be distinguished by a supported View selector (e.g. name, instrument kind) a renaming View recipe SHOULD be included in the warning.
- Otherwise (e.g., use of multiple units), the SDK SHOULD pass through the
data by reporting both
Metric
objects and emit a generic warning describing the duplicate instrument registration.
It is unspecified whether or under which conditions the same or different Instrument instance will be returned as a result of duplicate instrument registration. The term identical applied to Instruments describes instances where all identifying fields are equal. The term distinct applied to Instruments describes instances where at least one field value is different.
To accommodate the recommendations from the data model, the SDK MUST aggregate data from identical Instruments together in its export pipeline.
The name
of an Instrument is defined to be
case-insensitive. If an SDK uses a case-sensitive encoding to represent this
name
, a duplicate instrument registration will occur when a user passes
multiple casings of the same name
. When this happens, the Meter MUST return
an instrument using the first-seen instrument name and log an appropriate error
as described above.
For example, if a user creates an instrument with the name requestCount
and
then makes another request to the same Meter
to create an instrument with the
name RequestCount
, in both cases an instrument with the name requestCount
needs to be returned to the user and a log message needs to be emitted for the
second request.
When a Meter creates an instrument, it SHOULD validate the instrument name conforms to the instrument name syntax
If the instrument name does not conform to this syntax, the Meter SHOULD emit an error notifying the user about the invalid name. It is left unspecified if a valid instrument is also returned.
When a Meter creates an instrument, it SHOULD NOT validate the instrument unit. If a unit is not provided or the unit is null, the Meter MUST treat it the same as an empty unit string.
When a Meter creates an instrument, it SHOULD NOT validate the instrument description. If a description is not provided or the description is null, the Meter MUST treat it the same as an empty description string.
Status: Development
When a Meter creates an instrument, it SHOULD validate the instrument advisory parameters. If an advisory parameter is not valid, the Meter SHOULD emit an error notifying the user and proceed as if the parameter was not provided.
If multiple identical Instruments are created with different advisory parameters, the Meter MUST return an instrument using the first-seen advisory parameters and log an appropriate error as described in duplicate instrument registrations.
Status: Development
The instrument Enabled operation MUST return false
if any
of the following conditions are true, and true
otherwise:
- The MeterConfig of the
Meter
used to create the instrument has parameterdisabled=true
. - All resolved views for the instrument are configured with the Drop Aggregation.
Note: If a user makes no configuration changes, Enabled
returns true
since by
default MeterConfig.disabled=false
and instruments use the default
aggregation when no matching views match the instrument.
It is not necessary for implementations to ensure that changes
to MeterConfig.disabled
are immediately visible to callers of Enabled
. I.e.
atomic, volatile, synchronized, or equivalent memory semantics to avoid stale
reads are discouraged to prioritize performance over immediate consistency.
Status: Stable
Attributes which belong to Metrics are exempt from the common rules of attribute limits at this time. Attribute truncation or deletion could affect identity of metric time series and the topic requires further analysis.
Status: Stable
Exemplars are example data points for aggregated data. They provide specific
context to otherwise general aggregations. Exemplars allow correlation between
aggregated metric data and the original API calls where measurements are
recorded. Exemplars work for trace-metric correlation across any metric, not
just those that can also be derived from Span
s.
An Exemplar is a recorded Measurement that exposes the following pieces of information:
- The
value
of theMeasurement
that was recorded by the API call. - The
time
the API call was made to record aMeasurement
. - The set of Attributes associated with the
Measurement
not already included in a metric data point. - The associated trace id and span
id of the active Span
within Context of
the
Measurement
at API call time.
For example, if a user has configured a View
to preserve the attributes: X
and Y
, but the user records a measurement as follows:
const span = tracer.startSpan('makeRequest');
api.context.with(api.trace.setSpan(api.context.active(), span), () => {
// Record a measurement.
cache_miss_counter.add(1, {"X": "x-value", "Y": "y-value", "Z": "z-value"});
...
span.end();
})
Then an exemplar output in OTLP would consist of:
- The
value
of 1. - The
time
when theadd
method was called. - The
Attributes
of{"Z": "z-value"}
, as these are not preserved in the resulting metric point. - The trace/span id for the
makeRequest
span.
While the metric data point for the counter would carry the attributes X
and
Y
.
A Metric SDK MUST provide a mechanism to sample Exemplar
s from measurements
via the ExemplarFilter
and ExemplarReservoir
hooks.
Exemplar
sampling SHOULD be turned on by default. If Exemplar
sampling is
off, the SDK MUST NOT have overhead related to exemplar sampling.
A Metric SDK MUST allow exemplar sampling to leverage the configuration of metric aggregation. For example, Exemplar sampling of histograms should be able to leverage bucket boundaries.
A Metric SDK SHOULD provide configuration for Exemplar sampling, specifically:
ExemplarFilter
: filter which measurements can become exemplars.ExemplarReservoir
: storage and sampling of exemplars.
The ExemplarFilter
configuration MUST allow users to select between one of the
built-in ExemplarFilters. While ExemplarFilter
determines which measurements
are eligible for becoming an Exemplar
, the ExemplarReservoir
makes the
final decision if a measurement becomes an exemplar and is stored.
The ExemplarFilter SHOULD be a configuration parameter of a MeterProvider
for
an SDK. The default value SHOULD be TraceBased
. The filter configuration
SHOULD follow the environment variable specification.
An OpenTelemetry SDK MUST support the following filters:
An ExemplarFilter which makes all measurements eligible for being an Exemplar.
An ExemplarFilter which makes no measurements eligible for being an Exemplar. Using this ExemplarFilter is as good as disabling the Exemplar feature.
An ExemplarFilter which makes those measurements eligible for being an Exemplar, which are recorded in the context of a sampled parent span.
The ExemplarReservoir
interface MUST provide a method to offer measurements
to the reservoir and another to collect accumulated Exemplars.
A new ExemplarReservoir
MUST be created for every known timeseries data point,
as determined by aggregation and view configuration. This data point, and its
set of defining attributes, are referred to as the associated timeseries point.
The "offer" method SHOULD accept measurements, including:
- The
value
of the measurement. - The complete set of
Attributes
of the measurement. - The Context of the measurement, which covers the Baggage and the current active Span.
- A
timestamp
that best represents when the measurement was taken.
The "offer" method SHOULD have the ability to pull associated trace and span information without needing to record full context. In other words, current span context and baggage can be inspected at this point.
The "offer" method does not need to store all measurements it is given and
MAY further sample beyond the ExemplarFilter
.
The "offer" method MAY accept a filtered subset of Attributes
which diverge
from the timeseries the reservoir is associated with. This MUST be clearly
documented in the API and the reservoir MUST be given the Attributes
associated with its timeseries point either at construction so that additional
sampling performed by the reservoir has access to all attributes from a
measurement in the "offer" method. SDK authors are encouraged to benchmark
whether this option works best for their implementation.
The "collect" method MUST return accumulated Exemplar
s. Exemplars are expected
to abide by the AggregationTemporality
of any metric point they are recorded
with. In other words, Exemplars reported against a metric data point SHOULD have
occurred within the start/stop timestamps of that point. SDKs are free to
decide whether "collect" should also reset internal storage for delta temporal
aggregation collection, or use a more optimal implementation.
Exemplar
s MUST retain any attributes available in the measurement that
are not preserved by aggregation or view configuration for the associated
timeseries. Joining together attributes on an Exemplar
with
those available on its associated metric data point should result in the
full set of attributes from the original sample measurement.
The ExemplarReservoir
SHOULD avoid allocations when sampling exemplars.
The SDK MUST include two types of built-in exemplar reservoirs:
SimpleFixedSizeExemplarReservoir
AlignedHistogramBucketExemplarReservoir
By default:
- Explicit bucket histogram aggregation with more than 1 bucket SHOULD
use
AlignedHistogramBucketExemplarReservoir
. - Base2 Exponential Histogram Aggregation SHOULD use a
SimpleFixedSizeExemplarReservoir
with a reservoir equal to the smaller of the maximum number of buckets configured on the aggregation or twenty (e.g.min(20, max_buckets)
). - All other aggregations SHOULD use
SimpleFixedSizeExemplarReservoir
.
Exemplar default reservoirs MAY change in a minor version bump. No guarantees are made on the shape or statistical properties of returned exemplars.
This reservoir MUST use a uniformly-weighted sampling algorithm based on the number of samples the reservoir has seen so far to determine if the offered measurements should be sampled. For example, the simple reservoir sampling algorithm can be used:
if num_measurements_seen < num_buckets then
bucket = num_measurements_seen
else
bucket = random_integer(0, num_measurements_seen)
end
if bucket < num_buckets then
reservoir[bucket] = measurement
end
Any stateful portion of sampling computation SHOULD be reset every collection
cycle. For the above example, that would mean that the num_measurements_seen
count is reset every time the reservoir is collected.
This Exemplar reservoir MAY take a configuration parameter for the size of the
reservoir. If no size configuration is provided, the default size MAY be
the number of possible concurrent threads (e.g., number of CPUs) to help reduce
contention. Otherwise, a default size of 1
SHOULD be used.
This Exemplar reservoir MUST take a configuration parameter that is the configuration of a Histogram. This implementation MUST keep the last seen measurement that falls within a histogram bucket. The reservoir will accept measurements using the equivalent of the following naive algorithm:
bucket = find_histogram_bucket(measurement)
if bucket < num_buckets then
reservoir[bucket] = measurement
end
def find_histogram_bucket(measurement):
for boundary, idx in bucket_boundaries do
if value <= boundary then
return idx
end
end
return boundaries.length
This Exemplar reservoir MAY take a configuration parameter for the bucket boundaries used by the reservoir. The size of the reservoir is always the number of bucket boundaries plus one. This configuration parameter SHOULD have the same format as specifying bucket boundaries to Explicit Bucket Histogram Aggregation.
The SDK MUST provide a mechanism for SDK users to provide their own ExemplarReservoir implementation. This extension MUST be configurable on a metric View, although individual reservoirs MUST still be instantiated per metric-timeseries (see Exemplar Reservoir - Paragraph 2).
Status: Stable
MetricReader
is an SDK implementation object that provides the
common configurable aspects of the OpenTelemetry Metrics SDK and
determines the following capabilities:
- Collecting metrics from the SDK and any registered MetricProducers on demand.
- Handling the ForceFlush and Shutdown signals from the SDK.
To construct a MetricReader
when setting up an SDK, at least the following
SHOULD be provided:
- The
exporter
to use, which is aMetricExporter
instance. - The default output
aggregation
(optional), a function of instrument kind. This function SHOULD be obtained from theexporter
. If not configured, the default aggregation SHOULD be used. - The output
temporality
(optional), a function of instrument kind. This function SHOULD be obtained from theexporter
. If not configured, the Cumulative temporality SHOULD be used. - The default aggregation cardinality limit (optional) to use, a function of instrument kind. If not configured, a default value of 2000 SHOULD be used.
- Status: Development - The MetricFilter to apply to metrics and attributes during
MetricReader#Collect
. - Zero of more MetricProducers (optional) to collect metrics from in addition to metrics from the SDK.
Status: Development - A MetricReader
SHOULD provide the MetricFilter to the SDK or registered MetricProducer(s)
when calling the Produce
operation.
The MetricReader.Collect method allows general-purpose
MetricExporter
instances to explicitly initiate collection, commonly
used with pull-based metrics collection. A common implementation of
MetricReader
, the periodic exporting
MetricReader
SHOULD be provided to be used
typically with push-based metrics collection.
The MetricReader
MUST ensure that data points from OpenTelemetry
instruments are output in the configured aggregation
temporality for each instrument kind. For synchronous instruments with
Cumulative aggregation temporality, this means
converting Delta to Cumulative
aggregation temporality. For asynchronous instruments with Delta temporality,
this means
converting Cumulative to Delta
aggregation temporality.
The MetricReader
is not required to ensure data points from a non-SDK
MetricProducer are output in the configured aggregation
temporality, as these data points are not collected using OpenTelemetry
instruments.
The MetricReader
selection of temporality
as a function of instrument kind
influences the persistence of metric data points across collections. For
synchronous instruments with Cumulative aggregation
temporality, MetricReader.Collect MUST receive data points exposed
in previous collections regardless of whether new measurements have been
recorded. For synchronous instruments with Delta aggregation
temporality, MetricReader.Collect MUST only receive data points with
measurements recorded since the previous collection. For asynchronous
instruments with Delta or Cumulative aggregation
temporality, MetricReader.Collect MUST only receive data points with
measurements recorded since the previous collection. These rules apply to all
metrics, not just those whose point kinds
includes an aggregation temporality field.
The MetricReader
selection of temporality
as a function of instrument kind
influences the starting timestamp (i.e. StartTimeUnixNano
) of metrics data
points received by MetricReader.Collect. For instruments with
Cumulative aggregation temporality, successive data points received by
successive calls to MetricReader.Collect MUST repeat the same
starting timestamps (e.g. (T0, T1], (T0, T2], (T0, T3]
). For instruments with
Delta aggregation temporality, successive data points received by successive
calls to MetricReader.Collect MUST advance the starting timestamp (
e.g. (T0, T1], (T1, T2], (T2, T3]
). The ending timestamp (i.e. TimeUnixNano
)
MUST always be equal to time the metric data point took effect, which is equal
to when MetricReader.Collect was invoked. These rules apply to all
metrics, not just those whose point kinds includes
an aggregation temporality field.
See data model temporality for more details.
The SDK MUST support multiple MetricReader
instances to be registered on the
same MeterProvider
, and the MetricReader.Collect invocation on one
MetricReader
instance SHOULD NOT introduce side-effects to other MetricReader
instances. For example, if a MetricReader
instance is receiving metric data
points that have delta temporality, it is expected
that SDK will update the time range - e.g. from (Tn, Tn+1]
to (Tn+1, Tn+2] - ONLY for this particular
MetricReader
instance.
The SDK MUST NOT allow a MetricReader
instance to be registered on more than
one MeterProvider
instance.
+-----------------+ +--------------+
| | Metrics... | |
| In-memory state +------------> MetricReader |
| | | |
+-----------------+ +--------------+
+-----------------+ +--------------+
| | Metrics... | |
| In-memory state +------------> MetricReader |
| | | |
+-----------------+ +--------------+
The SDK SHOULD provide a way to allow MetricReader
to respond to
MeterProvider.ForceFlush and MeterProvider.Shutdown.
OpenTelemetry SDK authors MAY decide the language
idiomatic approach, for example, as OnForceFlush
and OnShutdown
callback
functions.
Collects the metrics from the SDK and any registered MetricProducers. If there are asynchronous SDK Instruments involved, their callback functions will be triggered.
Collect
SHOULD provide a way to let the caller know whether it succeeded,
failed or timed out. When the Collect
operation fails or times out on
some of the instruments, the SDK MAY return successfully collected results
and a failed reasons list to the caller.
Collect
does not have any required parameters, however, OpenTelemetry
SDK authors MAY choose to add parameters (e.g. callback,
filter, timeout). OpenTelemetry SDK authors MAY choose the
return value type, or do not return anything.
Collect
SHOULD invoke Produce on registered
MetricProducers. If the batch of metric points from
Produce
includes Resource information, Collect
MAY
replace the Resource
from the MetricProducer with the Resource
provided
when constructing the MeterProvider instead.
Note: it is expected that the MetricReader.Collect
implementations will be
provided by the SDK, so it is RECOMMENDED to prevent the user from accidentally
overriding it, if possible (e.g. final
in C++ and Java, sealed
in C#).
This method provides a way for the MetricReader
to do any cleanup required.
Shutdown
MUST be called only once for each MetricReader
instance. After the
call to Shutdown
, subsequent invocations to Collect
are not allowed. SDKs
SHOULD return some failure for these calls, if possible.
Shutdown
SHOULD provide a way to let the caller know whether it succeeded,
failed or timed out.
Shutdown
SHOULD complete or abort within some timeout. Shutdown
MAY be
implemented as a blocking API or an asynchronous API which notifies the caller
via a callback or an event. OpenTelemetry SDK authors MAY
decide if they want to make the shutdown timeout configurable.
This is an implementation of the MetricReader
which collects metrics based on
a user-configurable time interval, and passes the metrics to the configured
Push Metric Exporter.
Configurable parameters:
exportIntervalMillis
- the time interval in milliseconds between two consecutive exports. The default value is 60000 (milliseconds).exportTimeoutMillis
- how long the export can run before it is cancelled. The default value is 30000 (milliseconds).
The reader MUST synchronize calls to MetricExporter
's Export
to make sure that they are not invoked concurrently.
One possible implementation of periodic exporting MetricReader is to inherit
from MetricReader
and start a background task which calls the inherited
Collect()
method at the requested exportIntervalMillis
. The reader's
Collect()
method may still be invoked by other callers. For example,
- A user configures periodic exporting MetricReader with a push exporter and a 30 second interval.
- At the first 30 second interval, the background task calls
Collect()
which passes metrics to the push exporter. - After 15 seconds, the user decides to flush metrics for just this reader. They
call
Collect()
which passes metrics to the push exporter. - After another 15 seconds (at the end of the second 30 second interval),
the background task calls
Collect()
which passes metrics to the push exporter.
This method provides a way for the periodic exporting MetricReader so it can do as much as it could to collect and send the metrics.
ForceFlush
SHOULD collect metrics, call Export(batch)
and ForceFlush()
on the configured
Push Metric Exporter.
ForceFlush
SHOULD provide a way to let the caller know whether it succeeded,
failed or timed out. ForceFlush
SHOULD return some ERROR status if there
is an error condition; and if there is no error condition, it should return some
NO ERROR status, language implementations MAY decide how to model ERROR
and NO ERROR.
ForceFlush
SHOULD complete or abort within some timeout. ForceFlush
MAY be
implemented as a blocking API or an asynchronous API which notifies the caller
via a callback or an event.
Status: Stable
MetricExporter
defines the interface that protocol-specific exporters MUST
implement so that they can be plugged into OpenTelemetry SDK and support sending
of telemetry data.
Metric Exporters always have an associated MetricReader. The
aggregation
and temporality
properties used by the
OpenTelemetry Metric SDK are determined when registering Metric
Exporters through their associated MetricReader. OpenTelemetry
language implementations MAY support automatically configuring the
MetricReader to use for an Exporter.
The goal of the interface is to minimize the burden of implementation for protocol-dependent telemetry exporters. The protocol exporter is expected to be primarily a simple telemetry data encoder and transmitter.
Metric Exporter has access to the aggregated metrics
data. Metric Exporters SHOULD
report an error condition for data output by the MetricReader
with
unsupported Aggregation or Aggregation Temporality, as this condition
can be corrected by a change of MetricReader
configuration.
There could be multiple Push Metric Exporters or Pull
Metric Exporters or even a mixture of both configured at
the same time on a given MeterProvider
using one MetricReader
for each exporter. Different exporters
can run at different schedule, for example:
- Exporter A is a push exporter which sends data every 1 minute.
- Exporter B is a push exporter which sends data every 5 seconds.
- Exporter C is a pull exporter which reacts to a scraper over HTTP.
- Exporter D is a pull exporter which reacts to another scraper over a named pipe.
Push Metric Exporter sends metric data it receives from a paired MetricReader. Here are some examples:
- Sends the data based on a user configured schedule, e.g. every 1 minute. This MAY be accomplished by pairing the exporter with a periodic exporting MetricReader.
- Sends the data when there is a severe error.
The following diagram shows Push Metric Exporter
's relationship to other
components in the SDK:
+-----------------+ +---------------------------------+
| | Metrics... | |
| In-memory state +------------> Periodic exporting MetricReader |
| | | |
+-----------------+ | +-----------------------+ |
| | | |
| | MetricExporter (push) +-------> Another process
| | | |
| +-----------------------+ |
| |
+---------------------------------+
A Push Metric Exporter MUST support the following functions:
Exports a batch of Metric Points. Protocol exporters that will implement this function are typically expected to serialize and transmit the data to the destination.
The SDK MUST provide a way for the exporter to get the Meter
information (e.g. name, version, etc.) associated with each Metric Point
.
Export
should never be called concurrently with other Export
calls for the
same exporter instance.
Export
MUST NOT block indefinitely, there MUST be a reasonable upper limit
after which the call must time out with an error result (Failure).
Any retry logic that is required by the exporter is the responsibility of the exporter. The default SDK SHOULD NOT implement retry logic, as the required logic is likely to depend heavily on the specific protocol and backend the metrics are being sent to.
Parameters:
batch
- a batch of Metric Points. The exact
data type of the batch is language specific, typically it is some kind of list.
The exact type of Metric Point
is language specific, and is typically
optimized for high performance. Here are some examples:
+--------+ +--------+ +--------+
Batch: | Metric | | Metric | ... | Metric |
+---+----+ +--------+ +--------+
|
+--> name, unit, description, meter information, ...
|
| +-------------+ +-------------+ +-------------+
+--> MetricPoints: | MetricPoint | | MetricPoint | ... | MetricPoint |
+-----+-------+ +-------------+ +-------------+
|
+--> timestamps, attributes, value (or buckets), exemplars, ...
Refer to the Metric Points section from the Metrics Data Model specification for more details.
Note: it is highly recommended that implementors design the Metric
data type
based on the Data Model, rather than directly use the data
types generated from the proto
files
(because the types generated from proto files are not guaranteed to be backward
compatible).
Returns: ExportResult
ExportResult
is one of:
Success
- The batch has been successfully exported. For protocol exporters this typically means that the data is sent over the wire and delivered to the destination server.Failure
- exporting failed. The batch must be dropped. For example, this can happen when the batch contains bad data and cannot be serialized.
Note: this result may be returned via an async mechanism or a callback, if that is idiomatic for the language implementation.
This is a hint to ensure that the export of any Metrics
the exporter has
received prior to the call to ForceFlush
SHOULD be completed as soon as
possible, preferably before returning from this method.
ForceFlush
SHOULD provide a way to let the caller know whether it succeeded,
failed or timed out.
ForceFlush
SHOULD only be called in cases where it is absolutely necessary,
such as when using some FaaS providers that may suspend the process after an
invocation, but before the exporter exports the completed metrics.
ForceFlush
SHOULD complete or abort within some timeout. ForceFlush
can be
implemented as a blocking API or an asynchronous API which notifies the caller
via a callback or an event. OpenTelemetry SDK authors MAY
decide if they want to make the flush timeout configurable.
Shuts down the exporter. Called when SDK is shut down. This is an opportunity for exporter to do any cleanup required.
Shutdown SHOULD be called only once for each MetricExporter
instance. After
the call to Shutdown
subsequent calls to Export
are not allowed and should
return a Failure result.
Shutdown
SHOULD NOT block indefinitely (e.g. if it attempts to flush the data
and the destination is unavailable). OpenTelemetry SDK
authors MAY decide if they want to make the shutdown timeout configurable.
Pull Metric Exporter reacts to the metrics scrapers and reports the data passively. This pattern has been widely adopted by Prometheus.
Unlike Push Metric Exporter which can send data on its
own schedule, pull exporter can only send the data when it is being asked by the
scraper, and ForceFlush
would not make sense.
Implementors MAY choose the best idiomatic design for their language. For example, they could generalize the Push Metric Exporter interface design and use that for consistency, they could model the pull exporter as MetricReader, or they could design a completely different pull exporter interface. If the pull exporter is modeled as MetricReader, implementors MAY name the MetricExporter interface as PushMetricExporter to prevent naming confusion.
The following diagram gives some examples on how Pull Metric Exporter
can be
modeled to interact with other components in the SDK:
-
Model the pull exporter as MetricReader
+-----------------+ +-----------------------------+ | | Metrics... | | | In-memory state +------------> PrometheusExporter (pull) +---> Another process (scraper) | | | (modeled as a MetricReader) | +-----------------+ | | +-----------------------------+
-
Use the same MetricExporter design for both push and pull exporters
+-----------------+ +-----------------------------+ | | Metrics... | | | In-memory state +------------> Exporting MetricReader | | | | | +-----------------+ | +-----------------------+ | | | | | | | MetricExporter (pull) +------> Another process (scraper) | | | | | +-----------------------+ | | | +-----------------------------+
Status: Stable except where otherwise specified
MetricProducer
defines the interface which bridges to third-party metric
sources MUST implement, so they can be plugged into an OpenTelemetry
MetricReader as a source of aggregated metric data. The SDK's
in-memory state MAY implement the MetricProducer
interface for convenience.
MetricProducer
implementations SHOULD accept configuration for the
AggregationTemporality
of produced metrics. SDK authors MAY provide utility
libraries to facilitate conversion between delta and cumulative temporalities.
+-----------------+ +--------------+
| | Metrics... | |
| In-memory state +------------> MetricReader |
| | | |
+-----------------+ | |
| |
+-----------------+ | |
| | Metrics... | |
| MetricProducer +------------> |
| | | |
+-----------------+ +--------------+
When new OpenTelemetry integrations are added, the API is the preferred
integration point. The MetricProducer
is only meant for integrations that
bridge pre-processed data.
A MetricProducer
MUST support the following functions:
Produce
provides metrics from the MetricProducer to the caller. Produce
MUST return a batch of Metric Points, filtered by the optional
metricFilter
parameter. Implementation SHOULD use the filter as early as
possible to gain as much performance gain possible (memory allocation,
internal metric fetching, etc).
If the batch of Metric Points includes
resource information, Produce
SHOULD require a resource as a parameter.
Produce
does not have any other required parameters, however, OpenTelemetry
SDK authors MAY choose to add required or optional
parameters (e.g. timeout).
Produce
SHOULD provide a way to let the caller know whether it succeeded,
failed or timed out. When the Produce
operation fails, the MetricProducer
MAY return successfully collected results and a failed reasons list to the
caller.
If a batch of Metric Points can include
InstrumentationScope
information,
Produce
SHOULD include a single InstrumentationScope which identifies the
MetricProducer
.
Parameters:
Status: Development metricFilter
: An optional MetricFilter.
Status: Development
MetricFilter
defines the interface which enables the MetricReader's
registered MetricProducers or the SDK's MetricProducer to filter aggregated data points
(Metric Points) inside its Produce
operation.
The filtering is done at the MetricProducer for performance reasons.
The MetricFilter
allows filtering an entire metric stream - dropping or allowing all its attribute sets -
by its TestMetric
operation, which accepts the metric stream information
(scope, name, kind and unit) and returns an enumeration: Accept
, Drop
or Accept_Partial
. If the latter returned, the TestAttributes
operation
is to be called per attribute set of that metric stream, returning an enumeration
determining if the data point for that (metric stream, attributes) pair is to be
allowed in the result of the MetricProducer Produce
operation.
A MetricFilter
MUST support the following functions:
This operation is called once for every metric stream, in each MetricProducer Produce
operation.
Parameters:
instrumentationScope
: the metric stream instrumentation scopename
: the name of the metric streamkind
: the metric stream kindunit
: the metric stream unit
Returns: MetricFilterResult
MetricFilterResult
is one of:
Accept
- All attributes of the given metric stream are allowed (not to be filtered). This provides a "short-circuit" as there is no need to callTestAttributes
operation for each attribute set.Drop
- All attributes of the given metric stream are NOT allowed (filtered out - dropped). This provides a "short-circuit" as there is no need to callTestAttributes
operation for each attribute set, and no need to collect those data points be it synchronous or asynchronous: e.g. the callback for this given instrument does not need to be invoked.Accept_Partial
- Some attributes are allowed and some aren't, henceTestAttributes
operation must be called for each attribute set of that instrument.
An operation which determines for a given metric stream and attribute set if it should be allowed or filtered out.
This operation should only be called if TestMetric
operation returned Accept_Partial
for
the given metric stream arguments (instrumentationScope
, name
, kind
, unit
).
Parameters:
instrumentationScope
: the metric stream instrumentation scopename
: the name of the metric streamkind
: the metric stream kindunit
: the metric stream unitattributes
: the attributes
Returns: AttributesFilterResult
AttributesFilterResult
is one of:
Accept
- This givenattributes
are allowed (not to be filtered).Drop
- This givenattributes
are NOT allowed (filtered out - dropped).
The SDK MUST provide configuration according to the SDK environment variables specification.
The SDK MUST handle numerical limits in a graceful way according to Error handling in OpenTelemetry.
If the SDK receives float/double values from Instruments, it MUST handle all the possible values. For example, if the language runtime supports IEEE 754, the SDK needs to handle NaNs and Infinites.
It is unspecified how the SDK should handle the input limits. The SDK authors MAY leverage/follow the language runtime behavior for better performance, rather than perform a check on each value coming from the API.
It is unspecified how the SDK should handle the output limits (e.g. integer overflow). The SDK authors MAY rely on the language runtime behavior as long as errors/exceptions are taken care of.
Status: Stable
All the metrics components SHOULD allow new methods to be added to existing components without introducing breaking changes.
All the metrics SDK methods SHOULD allow optional parameter(s) to be added to existing methods without introducing breaking changes, if possible.
Status: Stable
For languages which support concurrent execution the Metrics SDKs provide specific guarantees and safeties.
MeterProvider - Meter creation, ForceFlush
and Shutdown
are safe to be
called concurrently.
ExemplarReservoir - all methods are safe to be called concurrently.
MetricReader - Collect
, ForceFlush
(for periodic exporting MetricReader)
and Shutdown
are safe to be called concurrently.
MetricExporter - ForceFlush
and Shutdown
are safe to be called
concurrently.