Status: Stable
Table of Contents
The Metrics API consists of these main components:
- MeterProvider is the entry point of the API. It provides
access to
Meters
. - Meter is the class responsible for creating
Instruments
. - Instrument is responsible for reporting Measurements.
Here is an example of the object hierarchy inside a process instrumented with the metrics API:
+-- MeterProvider(default)
|
+-- Meter(name='io.opentelemetry.runtime', version='1.0.0')
| |
| +-- Instrument<Asynchronous Gauge, int>(name='cpython.gc', attributes=['generation'], unit='kB')
| |
| +-- instruments...
|
+-- Meter(name='io.opentelemetry.contrib.mongodb.client', version='2.3.0')
|
+-- Instrument<Counter, int>(name='client.exception', attributes=['type'], unit='1')
|
+-- Instrument<Histogram, double>(name='client.duration', attributes=['net.peer.host', 'net.peer.port'], unit='ms')
|
+-- instruments...
+-- MeterProvider(custom)
|
+-- Meter(name='bank.payment', version='23.3.5')
|
+-- instruments...
Meter
s can be accessed with a MeterProvider
.
In implementations of the API, the MeterProvider
is expected to be the
stateful object that holds any configuration.
Normally, the MeterProvider
is expected to be accessed from a central place.
Thus, the API SHOULD provide a way to set/register and access a global default
MeterProvider
.
Notwithstanding any global MeterProvider
, some applications may want to or
have to use multiple MeterProvider
instances, e.g. to have different
configuration for each, or because its easier with dependency injection
frameworks. Thus, implementations of MeterProvider
SHOULD allow creating an
arbitrary number of MeterProvider
instances.
The MeterProvider
MUST provide the following functions:
- Get a
Meter
This API MUST accept the following parameters:
name
(required): This name SHOULD uniquely identify the instrumentation scope, such as the instrumentation library (e.g.io.opentelemetry.contrib.mongodb
), package, module or class name. If an application or library has built-in OpenTelemetry instrumentation, both Instrumented library and Instrumentation library may refer to the same library. In that scenario, thename
denotes a module name or component name within that library or application. In case an invalid name (null or empty string) is specified, a working Meter implementation MUST be returned as a fallback rather than returning null or throwing an exception, itsname
property SHOULD keep the original invalid value, and a message reporting that the specified value is invalid SHOULD be logged. A library, implementing the OpenTelemetry API may also ignore this name and return a default instance for all calls, if it does not support "named" functionality (e.g. an implementation which is not even observability-related). A MeterProvider could also return a no-op Meter here if application owners configure the SDK to suppress telemetry produced by this library.version
(optional): Specifies the version of the instrumentation scope if the scope has a version (e.g. a library version). Example value:1.0.0
.- [since 1.4.0]
schema_url
(optional): Specifies the Schema URL that should be recorded in the emitted telemetry. - [since 1.13.0]
attributes
(optional): Specifies the instrumentation scope attributes to associate with emitted telemetry.
Meters are identified by name
, version
, and schema_url
fields. When more
than one Meter
of the same name
, version
, and schema_url
is created, it
is unspecified whether or under which conditions the same or different Meter
instances are returned. It is a user error to create Meters with different
attributes but the same identity.
The term identical applied to Meters describes instances where all identifying fields are equal. The term distinct applied to Meters describes instances where at least one identifying field has a different value.
Implementations MUST NOT require users to repeatedly obtain a Meter
with
the same identity to pick up configuration changes. This can be
achieved either by allowing to work with an outdated configuration or by
ensuring that new configuration applies also to previously returned Meter
s.
Note: This could, for example, be implemented by storing any mutable
configuration in the MeterProvider
and having Meter
implementation objects
have a reference to the MeterProvider
from which they were obtained. If
configuration must be stored per-meter (such as disabling a certain meter), the
meter could, for example, do a look-up with its identity in a map
in the MeterProvider
, or the MeterProvider
could maintain a registry of all
returned Meter
s and actively update their configuration if it changes.
The effect of associating a Schema URL with a Meter
MUST be that the telemetry
emitted using the Meter
will be associated with the Schema URL, provided that
the emitted data format is capable of representing such association.
The meter is responsible for creating Instruments.
Note: Meter
SHOULD NOT be responsible for the configuration. This should be
the responsibility of the MeterProvider
instead.
The Meter
MUST provide functions to create new Instruments:
- Create a new Counter
- Create a new Asynchronous Counter
- Create a new Histogram
- Create a new Asynchronous Gauge
- Create a new UpDownCounter
- Create a new Asynchronous UpDownCounter
Also see the respective sections below for more information on instrument creation.
Instruments are used to report Measurements. Each Instrument will have the following fields:
- The
name
of the Instrument - The
kind
of the Instrument - whether it is a Counter or one of the other kinds, whether it is synchronous or asynchronous - An optional
unit
of measure - An optional
description
Instruments are associated with the Meter during creation. Instruments are identified by all of these fields.
Language-level features such as the distinction between integer and floating point numbers SHOULD be considered as identifying.
When more than one Instrument of the same name
is created for
identical Meters, denoted duplicate instrument registration, the
implementation MUST create a valid Instrument in every case. Here,
"valid" means an instrument that is functional and can be expected to
export data, despite potentially creating a semantic error in the
data
model.
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.
When more than one distinct Instrument is registered with the same
name
for identical Meters, the implementation SHOULD emit a warning
to the user informing them of duplicate registration conflict(s).
The warning helps to avoid the semantic error state described in the
OpenTelemetry Metrics data
model
when more than one Metric
is written for a given instrument name
and Meter identity by the same MeterProvider.
Distinct Meters MUST be treated as separate namespaces for the purposes of detecting duplicate instrument registration conflicts.
Instrument names MUST conform to the following syntax (described using the Augmented Backus-Naur Form):
instrument-name = ALPHA 0*62 ("_" / "." / "-" / ALPHA / DIGIT)
ALPHA = %x41-5A / %x61-7A; A-Z / a-z
DIGIT = %x30-39 ; 0-9
- They are not null or empty strings.
- They are case-insensitive, ASCII strings.
- The first character must be an alphabetic character.
- Subsequent characters must belong to the alphanumeric characters, '_', '.', and '-'.
- They can have a maximum length of 63 characters.
The unit
is an optional string provided by the author of the Instrument. It
SHOULD be treated as an opaque string from the API and SDK (e.g. the SDK is not
expected to validate the unit of measurement, or perform the unit conversion).
- If the
unit
is not provided or theunit
is null, the API and SDK MUST make sure that the behavior is the same as an emptyunit
string. - It MUST be case-sensitive (e.g.
kb
andkB
are different units), ASCII string. - It can have a maximum length of 63 characters. The number 63 is chosen to
allow the unit strings (including the
\0
terminator on certain language runtimes) to be stored and compared as fixed size array/struct when performance is critical.
The description
is an optional free-form text provided by the author of the
instrument. It MUST be treated as an opaque string from the API and SDK.
- If the
description
is not provided or thedescription
is null, the API and SDK MUST make sure that the behavior is the same as an emptydescription
string. - It MUST support BMP (Unicode Plane
0),
which is basically only the first three bytes of UTF-8 (or
utf8mb3
). OpenTelemetry API authors MAY decide if they want to support more Unicode Planes. - It MUST support at least 1023 characters. OpenTelemetry API authors MAY decide if they want to support more.
Instruments are categorized on whether they are synchronous or asynchronous:
-
Synchronous instruments (e.g. Counter) are meant to be invoked inline with application/business processing logic. For example, an HTTP client could use a Counter to record the number of bytes it has received. Measurements recorded by synchronous instruments can be associated with the Context.
-
Asynchronous instruments (e.g. Asynchronous Gauge) give the user a way to register callback function, and the callback function will be invoked only on demand (see SDK collection for reference). For example, a piece of embedded software could use an asynchronous gauge to collect the temperature from a sensor every 15 seconds, which means the callback function will only be invoked every 15 seconds. Measurements recorded by asynchronous instruments cannot be associated with the Context.
Please note that the term synchronous and asynchronous have nothing to do with the asynchronous pattern.
The API to construct synchronous instruments MUST accept the following parameters:
- The
name
of the Instrument, following the instrument naming rule. - An optional
unit
of measure, following the instrument unit rule. - An optional
description
, following the instrument description rule.
Asynchronous instruments have associated callback
functions which
are responsible for reporting Measurements. Callback
functions will be called only when the Meter is being observed. The
order of callback execution is not specified.
The API to construct asynchronous instruments MUST accept the following parameters:
- The
name
of the Instrument, following the instrument naming rule. - An optional
unit
of measure, following the instrument unit rule. - An optional
description
, following the instrument description rule. - Zero or more
callback
functions, responsible for reporting Measurement values of the created instrument.
The API MUST support creation of asynchronous instruments by passing
zero or more callback
functions to be permanently registered to the
newly created instrument.
A Callback is the conceptual entity created each time a callback
function is registered through an OpenTelemetry API.
The API SHOULD support registration of callback
functions associated with
asynchronous instruments after they are created.
Where the API supports registration of callback
functions after
asynchronous instrumentation creation, the user MUST be able to undo
registration of the specific callback after its registration by some means.
Every currently registered Callback associated with a set of instruments MUST be evaluated exactly once during collection prior to reading data for that instrument set.
Callback functions MUST be documented as follows for the end user:
- Callback functions SHOULD be reentrant safe. The SDK expects to evaluate callbacks for each MetricReader independently.
- Callback functions SHOULD NOT take an indefinite amount of time.
- Callback functions SHOULD NOT make duplicate observations (more than one
Measurement
with the sameattributes
) across all registered callbacks.
The resulting behavior when a callback violates any of these RECOMMENDATIONS is explicitly not specified at the API level.
OpenTelemetry API authors MAY decide what is the idiomatic approach for capturing measurements from callback functions. Here are some examples:
- Return a list (or tuple, generator, enumerator, etc.) of individual
Measurement
values. - Pass an Observable Result as a formal parameter of the callback,
where
result.Observe()
captures individualMeasurement
values.
Callbacks registered at the time of instrument creation MUST apply to the single instruments which is under construction.
Callbacks registered after the time of instrument creation MAY be associated with multiple instruments.
Idiomatic APIs for multiple-instrument Callbacks MUST distinguish the
instrument associated with each observed Measurement
value.
Multiple-instrument Callbacks MUST be associated at the time of
registration with a declared set of asynchronous instruments from the
same Meter
instance. This requirement that Instruments be
declaratively associated with Callbacks allows an SDK to execute only
those Callbacks that are necessary to evaluate instruments that are in
use by a configured View.
The API MUST treat observations from a single Callback as logically taking place at a single instant, such that when recorded, observations from a single callback MUST be reported with identical timestamps.
The API SHOULD provide some way to pass state
to the
callback. OpenTelemetry API authors MAY decide
what is the idiomatic approach (e.g. it could be an additional
parameter to the callback function, or captured by the lambda closure,
or something else).
Counter
is a synchronous Instrument which supports
non-negative increments.
Example uses for Counter
:
- count the number of bytes received
- count the number of requests completed
- count the number of accounts created
- count the number of checkpoints run
- count the number of HTTP 5xx errors
There MUST NOT be any API for creating a Counter
other than with a
Meter
. This MAY be called CreateCounter
. If strong type is
desired, OpenTelemetry API authors MAY decide the language
idiomatic name(s), for example CreateUInt64Counter
, CreateDoubleCounter
,
CreateCounter<UInt64>
, CreateCounter<double>
.
See the general requirements for synchronous instruments.
Here are some examples that OpenTelemetry API authors might consider:
# Python
exception_counter = meter.create_counter(name="exceptions", description="number of exceptions caught", value_type=int)
// C#
var counterExceptions = meter.CreateCounter<UInt64>("exceptions", description="number of exceptions caught");
readonly struct PowerConsumption
{
[HighCardinality]
string customer;
};
var counterPowerUsed = meter.CreateCounter<double, PowerConsumption>("power_consumption", unit="kWh");
Increment the Counter by a fixed amount.
This API SHOULD NOT return a value (it MAY return a dummy value if required by
certain programming languages or systems, for example null
, undefined
).
Required parameters:
- Optional attributes.
- The increment amount, which MUST be a non-negative numeric value.
The OpenTelemetry API authors MAY decide to allow flexible attributes to be passed in as arguments. If the attribute names and types are provided during the counter creation, the OpenTelemetry API authors MAY allow attribute values to be passed in using a more efficient way (e.g. strong typed struct allocated on the callstack, tuple). The API MUST allow callers to provide flexible attributes at invocation time rather than having to register all the possible attribute names during the instrument creation. Here are some examples that OpenTelemetry API authors might consider:
# Python
exception_counter.add(1, {"exception_type": "IOError", "handled_by_user": True})
exception_counter.add(1, exception_type="IOError", handled_by_user=True)
// C#
counterExceptions.Add(1, ("exception_type", "FileLoadException"), ("handled_by_user", true));
counterPowerUsed.Add(13.5, new PowerConsumption { customer = "Tom" });
counterPowerUsed.Add(200, new PowerConsumption { customer = "Jerry" }, ("is_green_energy", true));
Asynchronous Counter is an asynchronous Instrument which reports monotonically increasing value(s) when the instrument is being observed.
Example uses for Asynchronous Counter:
- CPU time, which could be reported for each thread, each process or the entire system. For example "the CPU time for process A running in user mode, measured in seconds".
- The number of page faults for each process.
There MUST NOT be any API for creating an Asynchronous Counter other than with a
Meter
. This MAY be called CreateObservableCounter
. If strong type
is desired, OpenTelemetry API authors MAY decide the
language idiomatic name(s), for example CreateUInt64ObservableCounter
,
CreateDoubleObservableCounter
, CreateObservableCounter<UInt64>
,
CreateObservableCounter<double>
.
It is highly recommended that implementations use the name ObservableCounter
(or any language idiomatic variation, e.g. observable_counter
) unless there is
a strong reason not to do so. Please note that the name has nothing to do with
asynchronous
pattern and
observer pattern.
See the general requirements for asynchronous instruments.
Note: Unlike Counter.Add() which takes the increment/delta value, the callback function reports the absolute value of the counter. To determine the reported rate the counter is changing, the difference between successive measurements is used.
OpenTelemetry API authors MAY decide what is the idiomatic approach. Here are some examples:
- Return a list (or tuple, generator, enumerator, etc.) of
Measurement
s. - Use an observable result argument to allow individual
Measurement
s to be reported.
User code is recommended not to provide more than one Measurement
with the
same attributes
in a single callback. If it happens, OpenTelemetry
SDK authors MAY decide how to handle it in the
SDK. For example, during the callback invocation if two
measurements value=1, attributes={pid:4, bitness:64}
and value=2, attributes={pid:4, bitness:64}
are reported, OpenTelemetry
SDK authors MAY decide to simply let them pass through (so
the downstream consumer can handle duplication), drop the entire data, pick the
last one, or something else. The API MUST treat observations from a single
callback as logically taking place at a single instant, such that when recorded,
observations from a single callback MUST be reported with identical timestamps.
The API SHOULD provide some way to pass state
to the callback. OpenTelemetry
API authors MAY decide what is the idiomatic approach (e.g.
it could be an additional parameter to the callback function, or captured by the
lambda closure, or something else).
Here are some examples that OpenTelemetry API authors might consider:
# Python
def pf_callback():
# Note: in the real world these would be retrieved from the operating system
return (
(8, ("pid", 0), ("bitness", 64)),
(37741921, ("pid", 4), ("bitness", 64)),
(10465, ("pid", 880), ("bitness", 32)),
)
meter.create_observable_counter(name="PF", description="process page faults", pf_callback)
# Python
def pf_callback(result):
# Note: in the real world these would be retrieved from the operating system
result.Observe(8, ("pid", 0), ("bitness", 64))
result.Observe(37741921, ("pid", 4), ("bitness", 64))
result.Observe(10465, ("pid", 880), ("bitness", 32))
meter.create_observable_counter(name="PF", description="process page faults", pf_callback)
// C#
// A simple scenario where only one value is reported
interface IAtomicClock
{
UInt64 GetCaesiumOscillates();
}
IAtomicClock clock = AtomicClock.Connect();
meter.CreateObservableCounter<UInt64>("caesium_oscillates", () => clock.GetCaesiumOscillates());
Asynchronous Counter uses an idiomatic interface for reporting
measurements through a callback
, which is registered during
Asynchronous Counter creation.
For callback functions registered after an asynchronous instrument is
created, the API is required to support a mechanism for
unregistration. For example, the object returned from register_callback
can support an unregister()
method directly.
# Python
class Device:
"""A device with one counter"""
def __init__(self, meter, x):
self.x = x
counter = meter.create_observable_counter(name="usage", description="count of items used")
self.cb = counter.register_callback(self.counter_callback)
def counter_callback(self, result):
result.Observe(self.read_counter(), {'x', self.x})
def read_counter(self):
return 100 # ...
def stop(self):
self.cb.unregister()
Histogram
is a synchronous Instrument which can be
used to report arbitrary values that are likely to be statistically meaningful.
It is intended for statistics such as histograms, summaries, and percentile.
Example uses for Histogram
:
- the request duration
- the size of the response payload
There MUST NOT be any API for creating a Histogram
other than with a
Meter
. This MAY be called CreateHistogram
. If strong type is
desired, OpenTelemetry API authors MAY decide the language
idiomatic name(s), for example CreateUInt64Histogram
, CreateDoubleHistogram
,
CreateHistogram<UInt64>
, CreateHistogram<double>
.
See the general requirements for synchronous instruments.
Here are some examples that OpenTelemetry API authors might consider:
# Python
http_server_duration = meter.create_histogram(
name="http.server.duration",
description="measures the duration of the inbound HTTP request",
unit="milliseconds",
value_type=float)
// C#
var httpServerDuration = meter.CreateHistogram<double>(
"http.server.duration",
description: "measures the duration of the inbound HTTP request",
unit: "milliseconds"
);
Updates the statistics with the specified amount.
This API SHOULD NOT return a value (it MAY return a dummy value if required by
certain programming languages or systems, for example null
, undefined
).
Parameters:
- The numeric value to record, which MUST be a non-negative numeric value.
- Optional attributes.
OpenTelemetry API authors MAY decide to allow flexible attributes to be passed in as individual arguments. OpenTelemetry API authors MAY allow attribute values to be passed in using a more efficient way (e.g. strong typed struct allocated on the callstack, tuple). Here are some examples that OpenTelemetry API authors might consider:
# Python
http_server_duration.Record(50, {"http.method": "POST", "http.scheme": "https"})
http_server_duration.Record(100, http_method="GET", http_scheme="http")
// C#
httpServerDuration.Record(50, ("http.method", "POST"), ("http.scheme", "https"));
httpServerDuration.Record(100, new HttpRequestAttributes { method = "GET", scheme = "http" });
Asynchronous Gauge is an asynchronous Instrument which reports non-additive value(s) (e.g. the room temperature - it makes no sense to report the temperature value from multiple rooms and sum them up) when the instrument is being observed.
Note: if the values are additive (e.g. the process heap size - it makes sense to report the heap size from multiple processes and sum them up, so we get the total heap usage), use Asynchronous Counter or Asynchronous UpDownCounter.
Example uses for Asynchronous Gauge:
- the current room temperature
- the CPU fan speed
There MUST NOT be any API for creating an Asynchronous Gauge other than with a
Meter
. This MAY be called CreateObservableGauge
. If strong type is
desired, OpenTelemetry API authors MAY decide the language
idiomatic name(s), for example CreateUInt64ObservableGauge
,
CreateDoubleObservableGauge
, CreateObservableGauge<UInt64>
,
CreateObservableGauge<double>
.
It is highly recommended that implementations use the name ObservableGauge
(or any language idiomatic variation, e.g. observable_gauge
) unless there is
a strong reason not to do so. Please note that the name has nothing to do with
asynchronous
pattern and
observer pattern.
See the general requirements for asynchronous instruments.
Here are some examples that OpenTelemetry API authors might consider:
# Python
def cpu_frequency_callback():
# Note: in the real world these would be retrieved from the operating system
return (
(3.38, ("cpu", 0), ("core", 0)),
(3.51, ("cpu", 0), ("core", 1)),
(0.57, ("cpu", 1), ("core", 0)),
(0.56, ("cpu", 1), ("core", 1)),
)
meter.create_observable_gauge(
name="cpu.frequency",
description="the real-time CPU clock speed",
callback=cpu_frequency_callback,
unit="GHz",
value_type=float)
# Python
def cpu_frequency_callback(result):
# Note: in the real world these would be retrieved from the operating system
result.Observe(3.38, ("cpu", 0), ("core", 0))
result.Observe(3.51, ("cpu", 0), ("core", 1))
result.Observe(0.57, ("cpu", 1), ("core", 0))
result.Observe(0.56, ("cpu", 1), ("core", 1))
meter.create_observable_gauge(
name="cpu.frequency",
description="the real-time CPU clock speed",
callback=cpu_frequency_callback,
unit="GHz",
value_type=float)
// C#
// A simple scenario where only one value is reported
meter.CreateObservableGauge<double>("temperature", () => sensor.GetTemperature());
Asynchronous Gauge uses an idiomatic interface for reporting
measurements through a callback
, which is registered during
Asynchronous Gauge creation.
For callback functions registered after an asynchronous instrument is
created, the API is required to support a mechanism for
unregistration. For example, the object returned from register_callback
can support an unregister()
method directly.
# Python
class Device:
"""A device with one gauge"""
def __init__(self, meter, x):
self.x = x
gauge = meter.create_observable_gauge(name="pressure", description="force/area")
self.cb = gauge.register_callback(self.gauge_callback)
def gauge_callback(self, result):
result.Observe(self.read_gauge(), {'x', self.x})
def read_gauge(self):
return 100 # ...
def stop(self):
self.cb.unregister()
UpDownCounter
is a synchronous Instrument which
supports increments and decrements.
Note: if the value is monotonically increasing, use Counter instead.
Example uses for UpDownCounter
:
- the number of active requests
- the number of items in a queue
An UpDownCounter
is intended for scenarios where the absolute values are not
pre-calculated, or fetching the "current value" requires extra effort. If the
pre-calculated value is already available or fetching the snapshot of the
"current value" is straightforward, use Asynchronous
UpDownCounter instead.
UpDownCounter supports counting the size of a collection incrementally, e.g. reporting the number of items in a concurrent bag by the "color" and "material" properties as they are added and removed.
Color | Material | Count |
---|---|---|
Red | Aluminum | 1 |
Red | Steel | 2 |
Blue | Aluminum | 0 |
Blue | Steel | 5 |
Yellow | Aluminum | 0 |
Yellow | Steel | 3 |
# Python
items_counter = meter.create_up_down_counter(
name="store.inventory",
description="the number of the items available")
def restock_item(color, material):
inventory.add_item(color=color, material=material)
items_counter.add(1, {"color": color, "material": material})
return true
def sell_item(color, material):
succeeded = inventory.take_item(color=color, material=material)
if succeeded:
items_counter.add(-1, {"color": color, "material": material})
return succeeded
There MUST NOT be any API for creating an UpDownCounter
other than with a
Meter
. This MAY be called CreateUpDownCounter
. If strong type is
desired, OpenTelemetry API authors MAY decide the language
idiomatic name(s), for example CreateInt64UpDownCounter
,
CreateDoubleUpDownCounter
, CreateUpDownCounter<Int64>
,
CreateUpDownCounter<double>
.
See the general requirements for synchronous instruments.
Here are some examples that OpenTelemetry API authors might consider:
# Python
customers_in_store = meter.create_up_down_counter(
name="grocery.customers",
description="measures the current customers in the grocery store",
value_type=int)
// C#
var customersInStore = meter.CreateUpDownCounter<int>(
"grocery.customers",
description: "measures the current customers in the grocery store",
);
Increment or decrement the UpDownCounter by a fixed amount.
This API SHOULD NOT return a value (it MAY return a dummy value if required by
certain programming languages or systems, for example null
, undefined
).
Parameters:
- The amount to be added, can be positive, negative or zero.
- Optional attributes.
OpenTelemetry API authors MAY decide to allow flexible attributes to be passed in as individual arguments. OpenTelemetry API authors MAY allow attribute values to be passed in using a more efficient way (e.g. strong typed struct allocated on the callstack, tuple). Here are some examples that OpenTelemetry API authors might consider:
# Python
customers_in_store.add(1, {"account.type": "commercial"})
customers_in_store.add(-1, account_type="residential")
// C#
customersInStore.Add(1, ("account.type", "commercial"));
customersInStore.Add(-1, new Account { Type = "residential" });
Asynchronous UpDownCounter is an asynchronous Instrument which reports additive value(s) (e.g. the process heap size - it makes sense to report the heap size from multiple processes and sum them up, so we get the total heap usage) when the instrument is being observed.
Note: if the value is monotonically increasing, use Asynchronous Counter instead; if the value is non-additive, use Asynchronous Gauge instead.
Example uses for Asynchronous UpDownCounter:
- the process heap size
- the approximate number of items in a lock-free circular buffer
There MUST NOT be any API for creating an Asynchronous UpDownCounter other than
with a Meter
. This MAY be called CreateObservableUpDownCounter
. If
strong type is desired, OpenTelemetry API authors MAY
decide the language idiomatic name(s), for example
CreateUInt64ObservableUpDownCounter
, CreateDoubleObservableUpDownCounter
,
CreateObservableUpDownCounter<UInt64>
,
CreateObservableUpDownCounter<double>
.
It is highly recommended that implementations use the name
ObservableUpDownCounter
(or any language idiomatic variation, e.g.
observable_updowncounter
) unless there is a strong reason not to do so. Please
note that the name has nothing to do with asynchronous
pattern and
observer pattern.
See the general requirements for asynchronous instruments.
Note: Unlike UpDownCounter.Add() which takes the increment/delta value, the callback function reports the absolute value of the Asynchronous UpDownCounter. To determine the reported rate the Asynchronous UpDownCounter is changing, the difference between successive measurements is used.
Here are some examples that OpenTelemetry API authors might consider:
# Python
def ws_callback():
# Note: in the real world these would be retrieved from the operating system
return (
(8, ("pid", 0), ("bitness", 64)),
(20, ("pid", 4), ("bitness", 64)),
(126032, ("pid", 880), ("bitness", 32)),
)
meter.create_observable_updowncounter(
name="process.workingset",
description="process working set",
callback=ws_callback,
unit="kB",
value_type=int)
# Python
def ws_callback(result):
# Note: in the real world these would be retrieved from the operating system
result.Observe(8, ("pid", 0), ("bitness", 64))
result.Observe(20, ("pid", 4), ("bitness", 64))
result.Observe(126032, ("pid", 880), ("bitness", 32))
meter.create_observable_updowncounter(
name="process.workingset",
description="process working set",
callback=ws_callback,
unit="kB",
value_type=int)
// C#
// A simple scenario where only one value is reported
meter.CreateObservableUpDownCounter<UInt64>("memory.physical.free", () => WMI.Query("FreePhysicalMemory"));
Asynchronous UpDownCounter uses an idiomatic interface for reporting
measurements through a callback
, which is registered during
Asynchronous Updowncounter creation.
For callback functions registered after an asynchronous instrument is
created, the API is required to support a mechanism for
unregistration. For example, the object returned from register_callback
can support an unregister()
method directly.
# Python
class Device:
"""A device with one updowncounter"""
def __init__(self, meter, x):
self.x = x
updowncounter = meter.create_observable_updowncounter(name="queue_size", description="items in process")
self.cb = updowncounter.register_callback(self.updowncounter_callback)
def updowncounter_callback(self, result):
result.Observe(self.read_updowncounter(), {'x', self.x})
def read_updowncounter(self):
return 100 # ...
def stop(self):
self.cb.unregister()
A Measurement
represents a data point reported via the metrics API to the SDK.
Please refer to the Metrics Programming Model
for the interaction between the API and SDK.
Measurement
s encapsulate:
- A value
Attributes
The Metrics API MAY support an interface allowing the use of multiple instruments from a single registered Callback. The API to register a new Callback SHOULD accept:
- A
callback
function - A list (or tuple, etc.) of Instruments used in the
callback
function.
It is RECOMMENDED that the API authors use one of the following forms
for the callback
function:
- The list (or tuple, etc.) returned by the
callback
function contains(Instrument, Measurement)
pairs. - the Observable Result parameter receives an additional
(Instrument, Measurement)
pairs
This interface is typically a more performant way to report multiple
measurements when they are obtained through an expensive process, such
as reading /proc
files or probing the garbage collection subsystem.
For example,
# Python
class Device:
"""A device with two instruments"""
def __init__(self, meter, property):
self.property = property
self.usage = meter.create_observable_counter(name="usage", description="count of items used")
self.pressure = meter.create_observable_gauge(name="pressure", description="force per unit area")
# Note the two associated instruments are passed to the callback.
meter.register_callback([self.usage, self.pressure], self.observe)
def observe(self, result):
usage, pressure = expensive_system_call()
result.observe(self.usage, usage, {'property', self.property})
result.observe(self.pressure, pressure, {'property', self.property})
All the metrics components SHOULD allow new APIs to be added to existing components without introducing breaking changes.
All the metrics APIs SHOULD allow optional parameter(s) to be added to existing APIs without introducing breaking changes, if possible.
For languages which support concurrent execution the Metrics APIs provide specific guarantees and safeties.
MeterProvider - all methods are safe to be called concurrently.
Meter - all methods are safe to be called concurrently.
Instrument - All methods of any Instrument are safe to be called concurrently.