- Motivation
- Solution Summary
- What is Out of Scope
- Use Cases
- Schema URL
- Schema Version Number
- Schema File
- OTLP Changes
- API and SDK Changes
- OpenTelemetry Schema 1.0.0
- Performance Impact
- Open Questions
- Future Possibilities
- Alternates Considered
- Prior Art
- Appendix A. Example Schema File
Telemetry sources such as instrumented applications and consumers of telemetry such as observability backends sometimes make implicit assumptions about the emitted telemetry. They assume that the telemetry will contain certain attributes or otherwise have a certain shape and composition of data (this is referred to as "telemetry schema" throughout this document).
This makes it difficult or impossible to change the composition of the emitted telemetry data without breaking the consumers. For example changing the name of an attribute of a span created by an instrumentation library can break the backend if the backend expects to find that attribute by its name.
Semantic conventions are an important part of this problem. These conventions define what names and values to use for span attributes, metric names and other fields. If semantic conventions are changed the existing implementations (telemetry source or consumers) need to be also changed correspondingly. Furthermore, to make things worse, the implementations of telemetry sources and implementations of telemetry consumers that work together and that depend on the changed semantic convention need to be changed simultaneously, otherwise such implementations will no longer work correctly together.
Essentially there is a coupling between 3 parties: 1) OpenTelemetry semantic conventions, 2) telemetry sources and 3) telemetry consumers. The coupling complicates the independent evolution of these 3 parties.
We recognize the following needs:
-
OpenTelemetry semantic conventions need to evolve over time. When conventions are first defined, mistakes are possible and we may want to fix the mistakes over time. We may also want to change conventions to re-group the attributes into different namespaces as our understanding of the attribute taxonomy improves.
-
Telemetry sources over time may want to change the schema of the telemetry they emit. This may be because for example the semantic conventions evolved and we want to make our telemetry match the newly introduced conventions.
-
In an observability system there may simultaneously exist telemetry sources that produce data that conforms to different telemetry schemas because different sources evolve at a different pace and are implemented and controlled by different entities.
-
Telemetry consumers have a need to understand what schema a particular piece of received telemetry confirms to. The consumers also need a way to be able to interpret the telemetry data that uses different telemetry schemas.
This document proposes a solution to these needs.
We believe that the 3 parties described above should be able to evolve independently over time, while continuously retaining the ability to correctly work together.
Telemetry Schemas are central to how we make this possible. Here is a summary of the proposal:
-
We introduce a file format for defining telemetry schemas.
-
Telemetry schemas are versioned. Over time the schema may evolve and telemetry sources may emit data confirming to newer versions of the schema.
-
Telemetry schemas explicitly define transformations that are necessary to convert telemetry data between different versions of the schema, provided that such conversions are possible. When conversions are not possible it constitutes a breaking change between versions.
-
Telemetry schemas are identified by Schema URLs, that are unique for each schema version.
-
Telemetry sources (e.g. instrumentation libraries) should include a schema URL in the emitted telemetry.
-
Telemetry consumers should pay attention to the schema of the received telemetry. If necessary, telemetry consumers may transform the telemetry data from the received schema version to the target schema version as expected at the point of use (e.g. a dashboard may define which schema version it expects).
-
OpenTelemetry will publish a telemetry schema as part of the specification. The schema will contain the list of transformations that semantic conventions undergo. The schema will be available to be referred and downloaded at well known URLs.
-
OpenTelemetry instrumentation libraries will include the OpenTelemetry Schema URL in all emitted telemetry.
-
OTLP will be modified to allow inclusion of a schema URL in the emitted telemetry.
-
Third-party libraries, instrumentation or applications will be advised to define and publish their own telemetry schema if it is completely different from OpenTelemetry schema (or use OpenTelemetry schema) and include the schema URL in the emitted telemetry.
-
The concept of schema defined in this proposal does not attempt to fully describe the shape of telemetry. The schema for example does not define all possible valid values for attributes or expected data types for metrics, etc. It is not a goal. Our goal is narrowly defined to solve the following problem only: to allow OpenTelemetry Semantic Conventions to evolve over time. For that reason this document is concerned with changes to the schema as opposed to the full state of the schema. We do not preclude this though: the schema file format is extensible and in the future may allow defining the full state of the schema, see Current State in Schema in Future Possibilities section).
-
We intentionally limit the types of transformations of schemas to the bare minimum that is necessary to handle the most common changes that we believe OpenTelemetry Semantic Conventions will require in the near future. More types of transformations may be proposed in the future. This proposal does not attempt to support a comprehensive set of possible transformation types that can handle all possible changes to schemas that we can imagine. That would be too complicated and very likely superfluous. Any new transformation types should be proposed and added in the future to the schema file format when there is an evidence that they are necessary for the evolution of OpenTelemetry.
This section shows a couple interesting use-cases for the telemetry schemas (other uses-cases are also possible, this is not an exhaustive list).
Here is an example on a schema-aware observability system:
Let's have a closer look at what happens with the Telemetry Source and Backend pair as the telemetry data is emitted, delivered and stored:
In this example the telemetry source produces spans that comply with version 1.2.0 of OpenTelemetry schema, where "deployment.environment" attribute is used to record that the span is coming from production.
The telemetry consumer desires to store the telemetry in version 1.1.0 of OpenTelemetry schema. The schema translator compares the schema_url in the received span with the desired schema and sees that a version conversion is needed. It then applies the change that is described in the schema file and renames the attribute from "deployment.environment" to "environment" before storing the span.
And here is for example how the schemas can be used to query stored data:
Here is a somewhat different use case, where the backend is not aware of schemas and we rely on OpenTelemetry Collector to translate the telemetry to a schema that the backend expects to receive. The "Schema Translate Processor" is configured, the target schema_url is specified and all telemetry data that passes through the Collector is converted to that target schema:
Schema URL is an identifier of a Schema. The URL specifies a location of a Schema File that can be retrieved (so it is a URL and not just a URI) using HTTP or HTTPS protocol.
Fetching the specified URL may return an HTTP redirect status code. The fetcher MUST follow the HTTP standard and honour the redirect response and fetch the file from the redirected URL.
The last part of the URL path is the version number of the schema.
http[s]://server[:port]/path/<version>
The part of the URL preceding the <version>
is called Schema Family
identifier. All schemas in one Schema Family have identical Schema Family
identifiers.
To create a new version of the schema copy the schema file for the last version in the schema family and add the definition of the new version. The schema file that corresponds to the new version must be retrievable at a new URL.
Important: schema files are immutable once they are published. Once the schema file is retrieved it is recommended to be cached permanently. Schema files may be also packaged at build time with the software that anticipates it may need the schema (e.g. the latest OpenTelemetry schema file can be packaged at build time with OpenTelemetry Collector's schema translation processor).
Version number follows the MAJOR.MINOR.PATCH format, similar to semver 2.0.
Version numbers use the ordering rules defined by semver 2.0 specification. See how ordering is used in the Order of Transformations. Other than the ordering rules the schema version numbers do not carry any other semantic meaning.
OpenTelemetry schema version numbers match OpenTelemetry specification version numbers, see more details here.
A Schema File is a YAML file that describes the schema of a particular version. It defines the transformations that can be used to convert the telemetry data represented in any other older compatible version of the same schema family to this schema version.
Here is the structure of the Schema File:
# Defines the file format. MUST be set to 1.0.0.
file_format: 1.0.0
# The Schema URL that this file is published at. The version number in the URL
# MUST match the highest version number in the "versions" section below.
# Note: the schema version number in the URL is not related in any way to
# the file_format setting above.
schema_url: https://opentelemetry.io/schemas/1.2.0
# Definitions for each schema version in this family.
# Note: the ordering of versions is defined according to semver
# version number ordering rules.
versions:
<version_number_last>:
# definitions for this version. See details below.
<version_number_previous>:
# definitions for previous version
...
<version_number_first>:
# Defines the first version.
Each <version_number>
section has the following structure:
<version_number>:
all:
changes:
# sequence of transformations.
resources:
changes:
# sequence of transformations.
spans:
changes:
# sequence of transformations.
span_events:
changes:
# sequence of transformations.
metrics:
changes:
# sequence of transformations.
logs:
changes:
# sequence of transformations.
There are 6 sub-sections under each version definition: "all", "resources", "spans", "span_events", "metrics", "logs". The last 5 sub-sections in this list contain definitions that apply only to the corresponding telemetry data type. Section "all" contains definitions that apply to all types of telemetry data.
Below we describe each section in detail.
"all" section in the schema file defines transformations. It must contain a sub-section named "changes" that defines how attributes were renamed from the previous version to this version.
The "changes" section is a sequence of transformations. Only one transformation is supported for section "all": "rename_attributes" transformation.
"rename_attributes" transformation requires a map of key/value pairs, where the key is the old name of the attribute used in the previous version, the value is the new name of the attribute starting from this version. Here is the structure:
all:
changes:
- rename_attributes:
attribute_map:
# map of key/values.
The transformations in section "all" apply to the following telemetry data: resource attributes, span attributes, span event attributes, log attributes, metric attributes.
Important: when converting from the previous version to the current version the transformation sequence in section "all" is performed first. After that the transformations in the specific section ("resources", "spans", "span_events", "metrics" or "logs") that correspond to the data type that is being converted are applied.
Note that "rename_attributes" transformation in most cases is reversible. It is possible to apply it backwards, so that telemetry data is converted from this version to the previous version. The only exception is when 2 or more different attributes in the previous version are renamed to the same attribute in the new version. In that case the reverse transformation is not possible since it would be ambiguous. When the reverse transformation is not possible it is considered an incompatible change. In this case the MAJOR version number of the schema SHOULD be increased in the new version.
"resources" section is very similar in its structure to "all". Like section "all" the transformations in section "resources" may contain only "rename_attributes" transformation.
The only difference from section "all" is that this transformation is only applicable to Resource data type.
Here is the structure:
resources:
changes:
- rename_attributes:
attribute_map:
# map of key/values. The keys are the old attribute name used
# the previous version, the values are the new attribute name
# starting from this version.
"spans" section in the schema file defines transformations that are applicable only to Span data type. It must contain a sub-section named "changes" that defines a sequence of actions to be applied to convert Spans from the previous version to this version.
One transformation is supported for section "span": "rename_attributes".
This is similar to the "rename_attributes" transformation supported in "all" and "resource" sections. In addition it is also possible to optionally specify spans that the transformation should apply to. Here is the structure:
spans:
changes:
- rename_attributes:
attribute_map:
# map of key/values. The keys are the old attribute name used
# in the previous version, the values are the new attribute name
# starting from this version.
"spans_events" section in the schema file defines transformations that are applicable only to Span's Event data type. It must contain a sub-section named "changes" that defines a sequence of actions to be applied to convert events from the previous version to this version.
Two transformations are supported for section "spans_events": "rename_events" and "rename_attributes".
This transformation allows to change event names. It is applied to all events or only to events of spans that have the specified name. Here is the structure:
span_events:
changes:
- rename_events:
name_map:
# The keys are old event name used in the previous version, the
# values are the new event name starting from this version.
This is similar to the "rename_attributes" transformation supported in "all" and "resource" sections. In addition it is also possible to optionally specify spans and events that the transformation should apply to (both optional conditions must match, if specified, for transformation to be applicable). Here is the structure:
span_events:
changes:
- rename_attributes:
attribute_map:
# map of key/values. The keys are the old attribute name used
# in the previous version, the values are the new attribute name
# starting from this version.
apply_to_spans:
# Optional span names to apply to. If empty applies to all spans.
apply_to_events:
# Optional event names to apply to. If empty applies to all events.
"metrics" section in the schema file defines transformations that are applicable only to Metric data type. It must contain a sub-section named "changes" that defines a sequence of actions to be applied to convert metrics from the previous version to this version.
Two transformations are supported for section "metrics": "rename_metrics" and "rename_attributes".
This transformation allows to change metric names. It is applied to all metrics. Here is the structure:
metrics:
changes:
- rename_metrics:
# map of key/values. The keys are the old metric name used
# in the previous version, the values are the new metric name
# starting from this version.
This is similar to the "rename_attributes" transformation supported in "span" sections. Here is the structure:
metrics:
changes:
- rename_attributes:
attribute_map:
# map of key/values. The keys are the old attribute name used
# in the previous version, the values are the new attribute name
# starting from this version.
apply_to_metrics:
# Optional. If it is missing the transformation is applied
# to all metrics. If it is present the transformation is applied
# only to the metrics with the name that is found in the sequence
# specified below.
"logs" section in the schema file defines transformations that are applicable only to the Log Record data type. It must contain a sub-section named "changes" that defines a sequence of actions to be applied to convert logs from the previous version to this version.
One transformation is supported for section "logs": "rename_attributes".
This is similar to the "rename_attributes" transformation supported in "spans" section. Here is the structure:
logs:
changes:
- rename_attributes:
attribute_map:
# map of key/values. The keys are the old attribute name used
# the previous version, the values are the new attribute name
# starting from this version.
When converting from older version X to newer version Y of the schema (both belonging to the same schema family) the transformations specified in each version in the range [X..Y] are applied one by one, i.e. first we convert from X to X+1, then from X+1 to X+2, ..., Y-2 to Y-1, Y-1 to Y. (Note, version numbers are not a continuum of integer numbers. The notion of adding a natural number 1 to the version number is a placeholder for the phrase "next newer version number that is defined for this schema family".)
The transformations that are listed for a particular version X describe changes that happened since the schema version that precedes version X and belongs to the same schema family. These transformations are listed in 6 sections: "all", "resources", "spans", "span_events", "metrics", "logs". Here is the order in which the transformations are applied:
-
Transformations in section "all" always are applied first, before any of the transformations in the other 5 sections.
-
Transformations in section "spans" are applied before transformations in section "span_events".
-
The order in which the transformations in remaining sections ("resources", "metrics", logs") are applied relative to each other or relative to "spans" section is undefined (since there are not-interdependencies, the order does not matter).
In the "changes" subsection of each particular one of these 6 sections the sequence of transformations is applied in the order it is listed in the schema file, from top to bottom.
When converting in the opposite direction, from newer version Y to older version X the order of transformation listed above is exactly the reverse, with each individual transformation also performing the reverse conversion.
The "file_format" setting in the schema file specifies the format version of the file. The format version follows the MAJOR.MINOR.PATCH format, similar to semver 2.0.
The "file_format" setting is used by consumers of the file to know if they are capable of interpreting the content of the file.
The current value for this setting is "1.0.0" and it will be published in OpenTelemetry specification once this OTEP is accepted. Any change to this number MUST follow the OTEP process and be published in the specification.
The current schema file format allows representing a limited set of transformations of telemetry data. We anticipate that in the future more types of transformations may be desirable to support or other, additional information may be desirable to record in the schema file (see Future Possibilities).
As the schema file format evolves over time the format version number SHOULD change according to the following rules:
-
PATCH number SHOULD be increased when the file format changes in a way that does not affect the existing consumers of the file. For example addition of a completely new section in the schema file that has no effect on existing sections and has no effect on any existing schema functionality may be done via incrementing the PATCH number only. This approach is only valid if the new setting in the file is completely and safely ignorable by all existing processing logic.
For example adding a completely new section that describes the full state of the schema has no effect on existing consumers which only care about "changes" section (unless we explicitly define the semantics of the new section such that it needs to be taken into account when processing schema changes). So, adding such a new section can be done using a PATCH number increase.
-
MINOR number SHOULD be increased if a new setting is added to the file format in a backward compatible manner. "Backward compatible" in this context means that consumers that are aware of the new MINOR number can consume the file of a particular MINOR version number or of any MINOR version number lower than that, provided that MAJOR version numbers are the same. Typically, this means that the added setting in file format is optional and the default value of the setting matches the behavior of the previous file format version.
Note: there is no "forward compatibility" based on MINOR version number. Consumers which support reading up to a particular MINOR version number SHOULD NOT attempt to consume files with higher MINOR version numbers.
-
MAJOR number SHOULD be increased if the file format is changed in an incompatible way. For example adding a new transformation type in the "changes" section is an incompatible change because it cannot be ignored by existing schema conversion logic, so such a change will require a new MAJOR number.
Correspondingly:
-
Consumers of the schema file SHOULD NOT attempt to interpret the schema file if the MAJOR version number is different (higher or lower) than what the consumer supports.
-
Consumers of the schema file SHOULD NOT attempt to interpret the schema file if the MINOR version number is higher than what the consumer supports.
-
Consumers MAY ignore the PATCH number.
To illustrate this with some examples:
File Format Version | Consumer's Expected Version | Consumer Can Read? |
1.0.0 | 1.0.0 | yes |
1.0.x | 1.0.y | yes, for any x and y. |
1.a.x | 1.b.x | if a<b then yes, otherwise no. |
2.0.0 | 1.x.y | no |
To allow carrying the Schema URL in emitted telemetry it is necessary to add a schema_url field to OTLP messages.
We add schema_url fields to the following messages:
message ResourceSpans {
...
// This schema_url applies to the "resource" field and to all spans and span events
// in the "instrumentation_library_spans" except the spans and span events which
// have a schema_url specified in the nested InstrumentationLibrarySpans message.
string schema_url = 3;
}
message InstrumentationLibrarySpans {
...
// This schema_url applies to all spans in the "spans" field regardless of the
// value of the schema_url field in the outer ResourceSpans message.
string schema_url = 3;
}
message ResourceMetrics {
...
// This schema_url applies to the "resource" field and to all metrics in the
// "instrumentation_library_metrics" except the metrics which have a schema_url
// specified in the nested InstrumentationLibraryMetrics message.
string schema_url = 3;
}
message InstrumentationLibraryMetrics {
...
// This schema_url applies to all metrics in the "metrics" field regardless of the
// value of the schema_url field in the outer ResourceMetrics message.
string schema_url = 3;
}
message ResourceLogs {
...
// This schema_url applies to the "resource" field and to all logs in the
// "instrumentation_library_logs" except the logs which have a schema_url
// specified in the nested InstrumentationLibraryLogs message.
string schema_url = 3;
}
message InstrumentationLibraryLogs {
...
// This schema_url applies to all logs in the "logs" field regardless of the
// value of the schema_url field in the outer ResourceLogs message.
string schema_url = 3;
}
The schema_url field in the ResourceSpans, ResourceMetrics, ResourceLogs messages applies to the contained Resource, Span, SpanEvent, Metric, LogRecord messages.
The schema_url field in the InstrumentationLibrarySpans message applies to the contained Span and SpanEvent messages.
The schema_url field in the InstrumentationLibraryMetrics message applies to the contained Metric messages.
The schema_url field in the InstrumentationLibraryLogs message applies to the contained LogRecord messages.
If schema_url field is non-empty both in Resource* message and in the contained InstrumentationLibrary* message then the value in InstrumentationLibrary* message takes the precedence.
The OpenTelemetry API needs to be changed to allow getting a Tracer/Meter/LogEmitter that is associated with a Schema URL (in addition to the association with instrumentation library name and version that is already supported).
This change needs to be done such that we do not break APIs that are already declared stable (particularly the Get Tracer API).
Depending on the language the following approaches are possible:
-
Add a third, optional parameter
schema_url
to Get Tracer/Get Meter/Get LogEmitter methods of corresponding providers. This may not be the right approach for languages where ABI stability is part of our guarantees since it likely breaks the ABI. -
Add a method overload that allows passing 3 parameters (instrumentation library name, version and schema url) to obtain a Tracer/Meter/LogEmitter. This is likely the preferred approach for languages where method overloads are possible.
-
If neither of the above 2 approaches are possible to do in non-breaking manner then the API may introduce a
SetSchema(schema_url)
method to Tracer/Meter/LogEmitter instance. The method MUST be called only once and MUST be called before any telemetry is emitted using the instance.
There may be other ways to modify the API to allow the association with a Schema URL. Language maintainers SHOULD choose the idiomatic way for their language.
The effect of associating a Schema URL with a Tracer/Meter/LogEmitter SHOULD be that the schema_url in the InstrumentationLibrarySpans, InstrumentationLibraryMetrics, InstrumentationLibraryLogs message for all the telemetry emitted with the associated Tracer/Meter/LogEmitter is populated with the provided Schema URL value.
If the Tracer/Meter/LogEmitter is not associated with a Schema URL then the exporter MUST leave the schema_url field in OTLP messages unset, in which case the application-wide Schema URL will apply.
Open Question: how to make it easy for instrumentation libraries to refer to a particular OpenTelemetry schema version and also make sure any semantic convention helpers the library uses (e.g. constants that define the semantic conventions) match exactly that same schema version? One possible solution is to introduce helper packages per schema version that the libraries can use, e.g. constants that define the semantic conventions and the corresponding schema version url. This should be likely the topic for a follow-up OTEP.
The SDK interface MUST provide a way for the user to optionally set an application-wide Schema URL. This Schema URL will be populated in all ResourceSpans, ResourceMetrics and ResourceLogs messages emitted by OTLP Exporter.
If the user does not set an application-wide Schema URL then the current Schema URL MUST be populated by OTLP Exporter in the messages, where "current" means the version of OpenTelemetry Schema against which the SDK is coded.
Note that if there is a schema url associated with instrumentation library it overrides the application-wide schema url as described here.
OpenTelemetry publishes it own schema at
https://opentelemetry.io/schemas/<version>
. The version number of the schema
is the same as the specification version number which publishes the schema.
Every time a new specification version is released a corresponding new schema
MUST be released simultaneously. If the specification release did not introduce
any change the "changes" section of the corresponding version in the schema file
will be empty.
As of the time of this proposal the specification is at version 1.2.0 and the corresponding schema file if it was published with the specification would look like this:
file_format: 1.0.0
schema_url: https://opentelemetry.io/schemas/1.2.0
versions:
1.2.0:
Since 1.2.0 is the first published version of OpenTelemetry schema there are no "changes" section and we omitted all previous versions from the file since there is nothing to record for earlier versions.
This file SHOULD be available for retrieval at https://opentelemetry.io/schemas/1.2.0
All OpenTelemetry instrumentation solutions will follow this schema.
Performance impact of the changes to OTLP protocol are negligible provided that schema conversion is not necessary. The cost of recording the schema_url by telemetry sources and the cost of checking the schema_url field in telemetry consumers is negligible compared to other costs. When the telemetry schema matches the expected schema there is no additional work involved at all.
When the schema version does not match and it is necessary to perform conversion the performance impact of the schema conversions depend on the volume and type of transformations can be significant. We benchmarked one use-case where the telemetry schema conversion of spans and metrics from one version to another is performed using a Go implementation.
The benchmark does the following:
-
Compares the CPU time necessary for schema conversion to the time necessary for Protobuf decoding. This is a useful comparison because telemetry consumers have to perform Protobuf decoding so it is the minimum baseline work against which we can measure the impact of the additional conversion work.
-
Uses a hypothetical schema version change where 20 attributes in semantic conventions were renamed.
-
Uses data composed of batches of 100 spans each with 10 attributes or 100 metric data points (Int64 Gauge type) with 2 attributes per data point. Each batch is associated with one resource that has 20 attributes.
Here are the benchmark results:
BenchmarkDecode/Trace/Attribs-8 6121 919271 ns/op
BenchmarkDecode/Metric/Int64-8 9516 635418 ns/op
BenchmarkDecodeAndConvertSchema/Trace/Attribs-8 5988 943158 ns/op
BenchmarkDecodeAndConvertSchema/Metric/Int64-8 8588 653266 ns/op
BenchmarkDecode is decoding time only. BenchmarkDecodeAndConvertSchema is decoding plus schema conversion time. We see that the processing time to do the conversion is about 3% of decoding time.
The benchmarking done is for illustration purposes only. Real-world results will depend on the composition of the data, the volume of transformations done during conversion, programming language used, etc. However, we feel that this one data point is still useful for understanding that the potential impact is acceptable (and likely will be a very small percentage of total processing most telemetry consumers do).
-
Do we need to support a concept of "pre-release" semantic conventions that can be broken freely and are not part of strict schema checks? Supposedly, this is already possible simply by avoiding introducing a new schema version when such semantic conventions change.
-
How to make it easy for instrumentation libraries to refer to a particular OpenTelemetry schema version and also make sure any semantic convention helpers the library uses (e.g. constants that define the semantic conventions) match exactly that same schema version? One possible solution is to introduce helper packages per schema version that the libraries can use, e.g. constants that define the semantic conventions and the corresponding schema version url. This should be likely the topic for a follow-up OTEP.
-
Should we make it possible to include the entire Schema File in OTLP requests in addition to the Schema URL so that recipients of the OTLP request do not have to fetch the Schema File (which may potentially be impossible if there are network issues)?
A schema can optionally have a parent schema (so for example a custom schema can be based on OpenTelemetry schema, which will be the parent in that case). A schema that does not have a parent is called a root schema (so OpenTelemetry schema will be a root schema). We may have more than one root schema (which opens up interesting possibilities, but this discussion is out of scope of this proposal).
All schemas therefore form a set of rooted trees, where nodes represent schema versions and pairs of nodes are connected via edges of two types: 1) parent-child relationship, 2) consecutive versions in the same schema family. Each edge in the tree represents a schema transformation.
Once we have the tree of schemas it is possible to then convert from a node in a tree to another node in a tree given that the nodes are connected via a path through edges.
Further research is needed in this area if we find that we need this concept of parent schemas.
The schema file in this OTEP describes changes from version to version. This is very useful for performing conversions between versions but it does not capture the current state of a particular version.
We can add an ability to specify the full current schema of each particular version in the schema file (in addition to the "changes" section). This will open up a few interesting possibilities:
-
Automatic validation that emitted telemetry confirms to the declared schema.
-
OpenTelemetry semantic conventions document can be automatically generated from this formal schema file. This will remove the need to have semantic conventions codified and generated from yaml files in the specification.
-
Consumers of telemetry can use this information to interpret the received telemetry.
-
It may be possible to auto-generate the "changes" section in schema files as a delta between full states of versions.
An example of what can be recorded as the "current state" is the encoding of the Body of the Log Records. It was described as a concept in this earlier proposal. The suggestion was to record the encoding of the Body field of Log Records, which can be also implemented as a new setting in the "current state" of the "logs" section in the schema file.
This OTEP introduces a limited set of transformations, while deliberately keeping the type of transformations to a minimum. It is easy to see that telemetry can evolve in other, more sophisticated ways over time (see e.g. this list).
More transformation types can be added in the future when there is a need to represent a particular change in the telemetry schema that is not possible with the current set of transformations. However, care should be taken to avoid introducing unnecessary or overly complicated transformation types, especially ones that cannot be applied on a local portion of telemetry data and requires a full state (e.g. transformations, such as aggregations, etc), since such transformations can place significant implementation burden on telemetry sources that wish to support the notion of telemetry schemas.
Depending on the changes that happened it may or may not be possible to convert telemetry from one version to another in a lossless and unambiguous way. When such conversion is possible we say that the schema is "convertible" from one particular version to another.
Generally, given an set of possible transformations and a pair of versions X and Y, it may be the converting telemetry from X to Y is possible, while the opposite direction - converting from Y to X is not possible.
The transformations defined in this proposal make all conversions from older schema versions to new versions possible. The opposite direction in some case may not be possible (see for example the explanation about reversible transformation all Section).
In the future we may also want to add ability to explicitly declare schema versions as non convertible. This may be necessary to express the fact that the schema has changed in a way that makes it incompatible, but schema file transformations alone are not expressive enough to describe that fact.
Instead of introducing formal schemas, schema files and version we can require that the instrumentation once it is created never changes. Attributes are never renamed, the emitted telemetry always remains the same, with the exception of changes that cannot affect existing telemetry consumers.
This was considered but does not seem to be an acceptable proposal. Mistakes happen, semantic conventions may need to be changed because they were incorrectly defined, there may be bugs in instrumentation that need to be fixed, etc. We believe that attempting to freeze the schema and only allow fully backward compatible changes in emitted telemetry is too restrictive and very difficult to follow long term.
This approach solves a smaller subset of schema evolution problems: change of names of attributes, metrics, etc.
When such changes happen the telemetry sources can continue producing telemetry using old attribute names, and also add attributes that have the new name and exact same value as the old attribute. So, the telemetry data at the same time has aliases of attributes recorded.
Because both old and new names are present in any emitted telemetry the consumers of the telemetry can just continue assuming that the attributes they are interested in are present. There is no formal schema management in this approach. We simply publish the same telemetry data in a way that both old and new consumers can find the bits they are looking for.
The benefit of this approach is that it is much simpler than proposed in this document.
The downsides of this approach are:
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It can handle limited types of schema changes. It is easy to demonstrate that some changes that can be easily handled via more formal schemas concept will fail if we use the aliases approach (e.g. swapping of attribute names X and Y cannot be handled by aliases).
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Over time more and more data should be published increasing the volume of the published data. Depending on how exactly the aliases handled we may need to duplicate a lot (e.g. if metric name has change we may have to produce the entire same metric twice, essentially duplicating the traffic) or may require breaking changes in the OpenTelemetry API or protocol to allow aliases natively.
Instead of performing transformations of the schema let telemetry consumers (backends) negotiate the version they expect to receive from the telemetry source.
The benefit of this approach is that the backend can support just one schema, there is no need to define transformation rules or do the transformations at all.
The downsides are:
-
Requires telemetry sources to be able to emit telemetry in multiple different schema versions, which is a significant burden on the telemetry sources. This is likely a dealbreaker.
-
Requires a communication channel from telemetry consumers to telemetry sources which currently does not exist (all communication is currently one-directional, from sources to consumers).
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OpenTelemetry Log Data Model: Body Meta-Data by Christian Beedgen.
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Generic event encoding schemas by Josh MacDonald.
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Structured Logging Payloads by David Poncelow.
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Versioning of Attributes and dataschema field in CloudEvents specification.
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Splunk sourcetype field.
# Defines the file format. MUST be set to 1.0.0.
file_format: 1.0.0
# The Schema URL that this file is published at. The version number in the URL
# MUST match the highest version number in the "versions" section below.
# Note: the schema version number in the URL is not related in any way to
# the file_format setting above.
schema_url: https://opentelemetry.io/schemas/1.1.0
# Definitions for each schema version in this family.
# Note: the ordering of versions is defined according to semver
# version number ordering rules.
versions:
1.1.0:
# Definitions for version 1.1.0.
all:
# Definitions that apply to all data types.
changes:
# Transformations to apply when converting from version 1.0.0 to 1.1.0.
- rename_attributes:
# map of key/values. The keys are the old attribute name used
# the previous version, the values are the new attribute name
# starting from this version.
# Rename k8s.* to kubernetes.*
k8s.cluster.name: kubernetes.cluster.name
k8s.namespace.name: kubernetes.namespace.name
k8s.node.name: kubernetes.node.name
k8s.node.uid: kubernetes.node.uid
k8s.pod.name: kubernetes.pod.name
k8s.pod.uid: kubernetes.pod.uid
k8s.container.name: kubernetes.container.name
k8s.replicaset.name: kubernetes.replicaset.name
k8s.replicaset.uid: kubernetes.replicaset.uid
k8s.cronjob.name: kubernetes.cronjob.name
k8s.cronjob.uid: kubernetes.cronjob.uid
k8s.job.name: kubernetes.job.name
k8s.job.uid: kubernetes.job.uid
k8s.statefulset.name: kubernetes.statefulset.name
k8s.statefulset.uid: kubernetes.statefulset.uid
k8s.daemonset.name: kubernetes.daemonset.name
k8s.daemonset.uid: kubernetes.daemonset.uid
k8s.deployment.name: kubernetes.deployment.name
k8s.deployment.uid: kubernetes.deployment.uid
resources:
# Definitions that apply to Resource data type.
changes:
- rename_attributes:
telemetry.auto.version: telemetry.auto_instr.version
spans:
# Definitions that apply to Span data type.
changes:
- rename_attributes:
attribute_map:
# map of key/values. The keys are the old attribute name used
# in the previous version, the values are the new attribute name
# starting from this version.
peer.service: peer.service.name
span_events:
# Definitions that apply to Span Event data type.
changes:
- rename_events:
# The keys are old event name used in the previous version, the
# values are the new event name starting from this version.
name_map: {stacktrace: stack_trace}
- rename_attributes:
attribute_map:
peer.service: peer.service.name
apply_to_events:
# Optional event names to apply to. If empty applies to all events.
- exception.stack_trace
metrics:
# Definitions that apply to Metric data type.
changes:
- rename_metrics:
# map of key/values. The keys are the old metric name used
# in the previous version, the values are the new metric name
# starting from this version.
container.cpu.usage.total: cpu.usage.total
container.memory.usage.max: memory.usage.max
- rename_attributes:
attribute_map:
status: state
apply_to_metrics:
# Optional. If it is missing the transformation is applied
# to all metrics. If it is present the transformation is applied
# only to the metrics with the name that is found in the sequence
# specified below.
- system.cpu.utilization
- system.memory.usage
- system.memory.utilization
- system.paging.usage
logs:
# Definitions that apply to LogRecord data type.
changes:
- rename_attributes:
attribute_map:
process.executable_name: process.executable.name
1.0.0:
# First version of this schema family.