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46ecbbea26
* lib/protoparser: adds opentelemetry parser app/{vmagent,vminsert}: adds opentelemetry ingestion path Adds ability to ingest data with opentelemetry protocol protobuf and json encoding is supported data converted into prometheus protobuf timeseries each data type has own converter and it may produce multiple timeseries from single datapoint (for summary and histogram). only cumulative aggregationFamily is supported for sum(prometheus counter) and histogram. Apply suggestions from code review Co-authored-by: Roman Khavronenko <roman@victoriametrics.com> updates deps fixes tests wip wip wip wip lib/protoparser/opentelemetry: moves to vtprotobuf generator go mod vendor lib/protoparse/opentelemetry: reduce memory allocations * wip - Remove support for JSON parsing, since it is too fragile and is rarely used in practice. The most clients send OpenTelemetry metrics in protobuf. The JSON parser can be added in the future if needed. - Remove unused code from lib/protoparser/opentelemetry/pb and lib/protoparser/opentelemetry/proto - Do not re-use protobuf message between ParseStream() calls, since there is high chance of high fragmentation of the re-used message because of too complex nested structure of the message. * wip * wip * wip --------- Co-authored-by: Aliaksandr Valialkin <valyala@victoriametrics.com>
662 lines
27 KiB
Protocol Buffer
662 lines
27 KiB
Protocol Buffer
// Copyright 2019, OpenTelemetry Authors
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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syntax = "proto3";
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package opentelemetry;
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import "lib/protoparser/opentelemetry/proto/common.proto";
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import "lib/protoparser/opentelemetry/proto/resource.proto";
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option csharp_namespace = "OpenTelemetry.Proto.Metrics.V1";
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option java_multiple_files = true;
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option java_package = "io.opentelemetry.proto.metrics.v1";
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option java_outer_classname = "MetricsProto";
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option go_package = "opentelemetry/pb";
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// MetricsData represents the metrics data that can be stored in a persistent
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// storage, OR can be embedded by other protocols that transfer OTLP metrics
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// data but do not implement the OTLP protocol.
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//
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// The main difference between this message and collector protocol is that
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// in this message there will not be any "control" or "metadata" specific to
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// OTLP protocol.
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//
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// When new fields are added into this message, the OTLP request MUST be updated
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// as well.
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message MetricsData {
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// An array of ResourceMetrics.
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// For data coming from a single resource this array will typically contain
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// one element. Intermediary nodes that receive data from multiple origins
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// typically batch the data before forwarding further and in that case this
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// array will contain multiple elements.
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repeated ResourceMetrics resource_metrics = 1;
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}
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// A collection of ScopeMetrics from a Resource.
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message ResourceMetrics {
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reserved 1000;
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// The resource for the metrics in this message.
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// If this field is not set then no resource info is known.
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Resource resource = 1;
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// A list of metrics that originate from a resource.
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repeated ScopeMetrics scope_metrics = 2;
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// This schema_url applies to the data in the "resource" field. It does not apply
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// to the data in the "scope_metrics" field which have their own schema_url field.
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string schema_url = 3;
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}
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// A collection of Metrics produced by an Scope.
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message ScopeMetrics {
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// A list of metrics that originate from an instrumentation library.
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repeated Metric metrics = 2;
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// This schema_url applies to all metrics in the "metrics" field.
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string schema_url = 3;
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}
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// Defines a Metric which has one or more timeseries. The following is a
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// brief summary of the Metric data model. For more details, see:
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//
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// https://github.com/open-telemetry/opentelemetry-specification/blob/main/specification/metrics/data-model.md
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//
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//
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// The data model and relation between entities is shown in the
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// diagram below. Here, "DataPoint" is the term used to refer to any
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// one of the specific data point value types, and "points" is the term used
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// to refer to any one of the lists of points contained in the Metric.
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//
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// - Metric is composed of a metadata and data.
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// - Metadata part contains a name, description, unit.
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// - Data is one of the possible types (Sum, Gauge, Histogram, Summary).
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// - DataPoint contains timestamps, attributes, and one of the possible value type
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// fields.
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//
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// Metric
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// +------------+
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// |name |
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// |description |
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// |unit | +------------------------------------+
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// |data |---> |Gauge, Sum, Histogram, Summary, ... |
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// +------------+ +------------------------------------+
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//
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// Data [One of Gauge, Sum, Histogram, Summary, ...]
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// +-----------+
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// |... | // Metadata about the Data.
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// |points |--+
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// +-----------+ |
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// | +---------------------------+
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// | |DataPoint 1 |
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// v |+------+------+ +------+ |
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// +-----+ ||label |label |...|label | |
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// | 1 |-->||value1|value2|...|valueN| |
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// +-----+ |+------+------+ +------+ |
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// | . | |+-----+ |
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// | . | ||value| |
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// | . | |+-----+ |
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// | . | +---------------------------+
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// | . | .
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// | . | .
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// | . | .
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// | . | +---------------------------+
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// | . | |DataPoint M |
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// +-----+ |+------+------+ +------+ |
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// | M |-->||label |label |...|label | |
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// +-----+ ||value1|value2|...|valueN| |
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// |+------+------+ +------+ |
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// |+-----+ |
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// ||value| |
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// |+-----+ |
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// +---------------------------+
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//
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// Each distinct type of DataPoint represents the output of a specific
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// aggregation function, the result of applying the DataPoint's
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// associated function of to one or more measurements.
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//
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// All DataPoint types have three common fields:
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// - Attributes includes key-value pairs associated with the data point
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// - TimeUnixNano is required, set to the end time of the aggregation
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// - StartTimeUnixNano is optional, but strongly encouraged for DataPoints
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// having an AggregationTemporality field, as discussed below.
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//
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// Both TimeUnixNano and StartTimeUnixNano values are expressed as
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// UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January 1970.
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//
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// # TimeUnixNano
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//
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// This field is required, having consistent interpretation across
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// DataPoint types. TimeUnixNano is the moment corresponding to when
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// the data point's aggregate value was captured.
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//
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// Data points with the 0 value for TimeUnixNano SHOULD be rejected
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// by consumers.
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//
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// # StartTimeUnixNano
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//
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// StartTimeUnixNano in general allows detecting when a sequence of
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// observations is unbroken. This field indicates to consumers the
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// start time for points with cumulative and delta
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// AggregationTemporality, and it should be included whenever possible
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// to support correct rate calculation. Although it may be omitted
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// when the start time is truly unknown, setting StartTimeUnixNano is
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// strongly encouraged.
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message Metric {
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reserved 4, 6, 8;
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// name of the metric, including its DNS name prefix. It must be unique.
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string name = 1;
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// description of the metric, which can be used in documentation.
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string description = 2;
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// unit in which the metric value is reported. Follows the format
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// described by http://unitsofmeasure.org/ucum.html.
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string unit = 3;
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// Data determines the aggregation type (if any) of the metric, what is the
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// reported value type for the data points, as well as the relatationship to
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// the time interval over which they are reported.
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oneof data {
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Gauge gauge = 5;
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Sum sum = 7;
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Histogram histogram = 9;
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ExponentialHistogram exponential_histogram = 10;
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Summary summary = 11;
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}
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}
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// Gauge represents the type of a scalar metric that always exports the
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// "current value" for every data point. It should be used for an "unknown"
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// aggregation.
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//
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// A Gauge does not support different aggregation temporalities. Given the
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// aggregation is unknown, points cannot be combined using the same
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// aggregation, regardless of aggregation temporalities. Therefore,
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// AggregationTemporality is not included. Consequently, this also means
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// "StartTimeUnixNano" is ignored for all data points.
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message Gauge {
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repeated NumberDataPoint data_points = 1;
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}
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// Sum represents the type of a scalar metric that is calculated as a sum of all
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// reported measurements over a time interval.
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message Sum {
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repeated NumberDataPoint data_points = 1;
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// aggregation_temporality describes if the aggregator reports delta changes
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// since last report time, or cumulative changes since a fixed start time.
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AggregationTemporality aggregation_temporality = 2;
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// If "true" means that the sum is monotonic.
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bool is_monotonic = 3;
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}
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// Histogram represents the type of a metric that is calculated by aggregating
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// as a Histogram of all reported measurements over a time interval.
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message Histogram {
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repeated HistogramDataPoint data_points = 1;
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// aggregation_temporality describes if the aggregator reports delta changes
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// since last report time, or cumulative changes since a fixed start time.
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AggregationTemporality aggregation_temporality = 2;
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}
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// ExponentialHistogram represents the type of a metric that is calculated by aggregating
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// as a ExponentialHistogram of all reported double measurements over a time interval.
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message ExponentialHistogram {
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repeated ExponentialHistogramDataPoint data_points = 1;
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// aggregation_temporality describes if the aggregator reports delta changes
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// since last report time, or cumulative changes since a fixed start time.
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AggregationTemporality aggregation_temporality = 2;
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}
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// Summary metric data are used to convey quantile summaries,
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// a Prometheus (see: https://prometheus.io/docs/concepts/metric_types/#summary)
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// and OpenMetrics (see: https://github.com/OpenObservability/OpenMetrics/blob/4dbf6075567ab43296eed941037c12951faafb92/protos/prometheus.proto#L45)
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// data type. These data points cannot always be merged in a meaningful way.
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// While they can be useful in some applications, histogram data points are
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// recommended for new applications.
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message Summary {
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repeated SummaryDataPoint data_points = 1;
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}
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// AggregationTemporality defines how a metric aggregator reports aggregated
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// values. It describes how those values relate to the time interval over
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// which they are aggregated.
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enum AggregationTemporality {
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// UNSPECIFIED is the default AggregationTemporality, it MUST not be used.
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AGGREGATION_TEMPORALITY_UNSPECIFIED = 0;
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// DELTA is an AggregationTemporality for a metric aggregator which reports
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// changes since last report time. Successive metrics contain aggregation of
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// values from continuous and non-overlapping intervals.
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//
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// The values for a DELTA metric are based only on the time interval
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// associated with one measurement cycle. There is no dependency on
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// previous measurements like is the case for CUMULATIVE metrics.
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//
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// For example, consider a system measuring the number of requests that
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// it receives and reports the sum of these requests every second as a
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// DELTA metric:
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//
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// 1. The system starts receiving at time=t_0.
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// 2. A request is received, the system measures 1 request.
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// 3. A request is received, the system measures 1 request.
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// 4. A request is received, the system measures 1 request.
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// 5. The 1 second collection cycle ends. A metric is exported for the
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// number of requests received over the interval of time t_0 to
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// t_0+1 with a value of 3.
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// 6. A request is received, the system measures 1 request.
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// 7. A request is received, the system measures 1 request.
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// 8. The 1 second collection cycle ends. A metric is exported for the
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// number of requests received over the interval of time t_0+1 to
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// t_0+2 with a value of 2.
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AGGREGATION_TEMPORALITY_DELTA = 1;
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// CUMULATIVE is an AggregationTemporality for a metric aggregator which
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// reports changes since a fixed start time. This means that current values
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// of a CUMULATIVE metric depend on all previous measurements since the
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// start time. Because of this, the sender is required to retain this state
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// in some form. If this state is lost or invalidated, the CUMULATIVE metric
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// values MUST be reset and a new fixed start time following the last
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// reported measurement time sent MUST be used.
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//
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// For example, consider a system measuring the number of requests that
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// it receives and reports the sum of these requests every second as a
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// CUMULATIVE metric:
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//
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// 1. The system starts receiving at time=t_0.
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// 2. A request is received, the system measures 1 request.
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// 3. A request is received, the system measures 1 request.
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// 4. A request is received, the system measures 1 request.
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// 5. The 1 second collection cycle ends. A metric is exported for the
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// number of requests received over the interval of time t_0 to
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// t_0+1 with a value of 3.
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// 6. A request is received, the system measures 1 request.
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// 7. A request is received, the system measures 1 request.
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// 8. The 1 second collection cycle ends. A metric is exported for the
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// number of requests received over the interval of time t_0 to
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// t_0+2 with a value of 5.
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// 9. The system experiences a fault and loses state.
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// 10. The system recovers and resumes receiving at time=t_1.
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// 11. A request is received, the system measures 1 request.
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// 12. The 1 second collection cycle ends. A metric is exported for the
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// number of requests received over the interval of time t_1 to
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// t_0+1 with a value of 1.
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//
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// Note: Even though, when reporting changes since last report time, using
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// CUMULATIVE is valid, it is not recommended. This may cause problems for
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// systems that do not use start_time to determine when the aggregation
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// value was reset (e.g. Prometheus).
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AGGREGATION_TEMPORALITY_CUMULATIVE = 2;
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}
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// DataPointFlags is defined as a protobuf 'uint32' type and is to be used as a
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// bit-field representing 32 distinct boolean flags. Each flag defined in this
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// enum is a bit-mask. To test the presence of a single flag in the flags of
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// a data point, for example, use an expression like:
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//
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// (point.flags & FLAG_NO_RECORDED_VALUE) == FLAG_NO_RECORDED_VALUE
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//
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enum DataPointFlags {
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FLAG_NONE = 0;
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// This DataPoint is valid but has no recorded value. This value
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// SHOULD be used to reflect explicitly missing data in a series, as
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// for an equivalent to the Prometheus "staleness marker".
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FLAG_NO_RECORDED_VALUE = 1;
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// Bits 2-31 are reserved for future use.
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}
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// NumberDataPoint is a single data point in a timeseries that describes the
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// time-varying scalar value of a metric.
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message NumberDataPoint {
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reserved 1;
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// The set of key/value pairs that uniquely identify the timeseries from
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// where this point belongs. The list may be empty (may contain 0 elements).
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// Attribute keys MUST be unique (it is not allowed to have more than one
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// attribute with the same key).
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repeated KeyValue attributes = 7;
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// StartTimeUnixNano is optional but strongly encouraged, see the
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// the detailed comments above Metric.
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//
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// Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January
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// 1970.
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fixed64 start_time_unix_nano = 2;
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// TimeUnixNano is required, see the detailed comments above Metric.
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//
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// Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January
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// 1970.
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fixed64 time_unix_nano = 3;
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// The value itself. A point is considered invalid when one of the recognized
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// value fields is not present inside this oneof.
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oneof value {
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double as_double = 4;
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sfixed64 as_int = 6;
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}
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// (Optional) List of exemplars collected from
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// measurements that were used to form the data point
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repeated Exemplar exemplars = 5;
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// Flags that apply to this specific data point. See DataPointFlags
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// for the available flags and their meaning.
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uint32 flags = 8;
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}
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// HistogramDataPoint is a single data point in a timeseries that describes the
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// time-varying values of a Histogram. A Histogram contains summary statistics
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// for a population of values, it may optionally contain the distribution of
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// those values across a set of buckets.
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//
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// If the histogram contains the distribution of values, then both
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// "explicit_bounds" and "bucket counts" fields must be defined.
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// If the histogram does not contain the distribution of values, then both
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// "explicit_bounds" and "bucket_counts" must be omitted and only "count" and
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// "sum" are known.
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message HistogramDataPoint {
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reserved 1;
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// The set of key/value pairs that uniquely identify the timeseries from
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// where this point belongs. The list may be empty (may contain 0 elements).
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// Attribute keys MUST be unique (it is not allowed to have more than one
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// attribute with the same key).
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repeated KeyValue attributes = 9;
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// StartTimeUnixNano is optional but strongly encouraged, see the
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// the detailed comments above Metric.
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//
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// Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January
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// 1970.
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fixed64 start_time_unix_nano = 2;
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// TimeUnixNano is required, see the detailed comments above Metric.
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//
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// Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January
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// 1970.
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fixed64 time_unix_nano = 3;
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// count is the number of values in the population. Must be non-negative. This
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// value must be equal to the sum of the "count" fields in buckets if a
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// histogram is provided.
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fixed64 count = 4;
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// sum of the values in the population. If count is zero then this field
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// must be zero.
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//
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// Note: Sum should only be filled out when measuring non-negative discrete
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// events, and is assumed to be monotonic over the values of these events.
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// Negative events *can* be recorded, but sum should not be filled out when
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// doing so. This is specifically to enforce compatibility w/ OpenMetrics,
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// see: https://github.com/OpenObservability/OpenMetrics/blob/main/specification/OpenMetrics.md#histogram
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optional double sum = 5;
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// bucket_counts is an optional field contains the count values of histogram
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// for each bucket.
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//
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// The sum of the bucket_counts must equal the value in the count field.
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//
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// The number of elements in bucket_counts array must be by one greater than
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// the number of elements in explicit_bounds array.
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repeated fixed64 bucket_counts = 6;
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// explicit_bounds specifies buckets with explicitly defined bounds for values.
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//
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// The boundaries for bucket at index i are:
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//
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// (-infinity, explicit_bounds[i]] for i == 0
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// (explicit_bounds[i-1], explicit_bounds[i]] for 0 < i < size(explicit_bounds)
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// (explicit_bounds[i-1], +infinity) for i == size(explicit_bounds)
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//
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// The values in the explicit_bounds array must be strictly increasing.
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//
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// Histogram buckets are inclusive of their upper boundary, except the last
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// bucket where the boundary is at infinity. This format is intentionally
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// compatible with the OpenMetrics histogram definition.
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repeated double explicit_bounds = 7;
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// (Optional) List of exemplars collected from
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// measurements that were used to form the data point
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repeated Exemplar exemplars = 8;
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// Flags that apply to this specific data point. See DataPointFlags
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// for the available flags and their meaning.
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uint32 flags = 10;
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// min is the minimum value over (start_time, end_time].
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optional double min = 11;
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// max is the maximum value over (start_time, end_time].
|
|
optional double max = 12;
|
|
}
|
|
|
|
// ExponentialHistogramDataPoint is a single data point in a timeseries that describes the
|
|
// time-varying values of a ExponentialHistogram of double values. A ExponentialHistogram contains
|
|
// summary statistics for a population of values, it may optionally contain the
|
|
// distribution of those values across a set of buckets.
|
|
//
|
|
message ExponentialHistogramDataPoint {
|
|
// The set of key/value pairs that uniquely identify the timeseries from
|
|
// where this point belongs. The list may be empty (may contain 0 elements).
|
|
// Attribute keys MUST be unique (it is not allowed to have more than one
|
|
// attribute with the same key).
|
|
repeated KeyValue attributes = 1;
|
|
|
|
// StartTimeUnixNano is optional but strongly encouraged, see the
|
|
// the detailed comments above Metric.
|
|
//
|
|
// Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January
|
|
// 1970.
|
|
fixed64 start_time_unix_nano = 2;
|
|
|
|
// TimeUnixNano is required, see the detailed comments above Metric.
|
|
//
|
|
// Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January
|
|
// 1970.
|
|
fixed64 time_unix_nano = 3;
|
|
|
|
// count is the number of values in the population. Must be
|
|
// non-negative. This value must be equal to the sum of the "bucket_counts"
|
|
// values in the positive and negative Buckets plus the "zero_count" field.
|
|
fixed64 count = 4;
|
|
|
|
// sum of the values in the population. If count is zero then this field
|
|
// must be zero.
|
|
//
|
|
// Note: Sum should only be filled out when measuring non-negative discrete
|
|
// events, and is assumed to be monotonic over the values of these events.
|
|
// Negative events *can* be recorded, but sum should not be filled out when
|
|
// doing so. This is specifically to enforce compatibility w/ OpenMetrics,
|
|
// see: https://github.com/OpenObservability/OpenMetrics/blob/main/specification/OpenMetrics.md#histogram
|
|
optional double sum = 5;
|
|
|
|
// scale describes the resolution of the histogram. Boundaries are
|
|
// located at powers of the base, where:
|
|
//
|
|
// base = (2^(2^-scale))
|
|
//
|
|
// The histogram bucket identified by `index`, a signed integer,
|
|
// contains values that are greater than (base^index) and
|
|
// less than or equal to (base^(index+1)).
|
|
//
|
|
// The positive and negative ranges of the histogram are expressed
|
|
// separately. Negative values are mapped by their absolute value
|
|
// into the negative range using the same scale as the positive range.
|
|
//
|
|
// scale is not restricted by the protocol, as the permissible
|
|
// values depend on the range of the data.
|
|
sint32 scale = 6;
|
|
|
|
// zero_count is the count of values that are either exactly zero or
|
|
// within the region considered zero by the instrumentation at the
|
|
// tolerated degree of precision. This bucket stores values that
|
|
// cannot be expressed using the standard exponential formula as
|
|
// well as values that have been rounded to zero.
|
|
//
|
|
// Implementations MAY consider the zero bucket to have probability
|
|
// mass equal to (zero_count / count).
|
|
fixed64 zero_count = 7;
|
|
|
|
// positive carries the positive range of exponential bucket counts.
|
|
Buckets positive = 8;
|
|
|
|
// negative carries the negative range of exponential bucket counts.
|
|
Buckets negative = 9;
|
|
|
|
// Buckets are a set of bucket counts, encoded in a contiguous array
|
|
// of counts.
|
|
message Buckets {
|
|
// Offset is the bucket index of the first entry in the bucket_counts array.
|
|
//
|
|
// Note: This uses a varint encoding as a simple form of compression.
|
|
sint32 offset = 1;
|
|
|
|
// Count is an array of counts, where count[i] carries the count
|
|
// of the bucket at index (offset+i). count[i] is the count of
|
|
// values greater than base^(offset+i) and less or equal to than
|
|
// base^(offset+i+1).
|
|
//
|
|
// Note: By contrast, the explicit HistogramDataPoint uses
|
|
// fixed64. This field is expected to have many buckets,
|
|
// especially zeros, so uint64 has been selected to ensure
|
|
// varint encoding.
|
|
repeated uint64 bucket_counts = 2;
|
|
}
|
|
|
|
// Flags that apply to this specific data point. See DataPointFlags
|
|
// for the available flags and their meaning.
|
|
uint32 flags = 10;
|
|
|
|
// (Optional) List of exemplars collected from
|
|
// measurements that were used to form the data point
|
|
repeated Exemplar exemplars = 11;
|
|
|
|
// min is the minimum value over (start_time, end_time].
|
|
optional double min = 12;
|
|
|
|
// max is the maximum value over (start_time, end_time].
|
|
optional double max = 13;
|
|
}
|
|
|
|
// SummaryDataPoint is a single data point in a timeseries that describes the
|
|
// time-varying values of a Summary metric.
|
|
message SummaryDataPoint {
|
|
reserved 1;
|
|
|
|
// The set of key/value pairs that uniquely identify the timeseries from
|
|
// where this point belongs. The list may be empty (may contain 0 elements).
|
|
// Attribute keys MUST be unique (it is not allowed to have more than one
|
|
// attribute with the same key).
|
|
repeated KeyValue attributes = 7;
|
|
|
|
// StartTimeUnixNano is optional but strongly encouraged, see the
|
|
// the detailed comments above Metric.
|
|
//
|
|
// Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January
|
|
// 1970.
|
|
fixed64 start_time_unix_nano = 2;
|
|
|
|
// TimeUnixNano is required, see the detailed comments above Metric.
|
|
//
|
|
// Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January
|
|
// 1970.
|
|
fixed64 time_unix_nano = 3;
|
|
|
|
// count is the number of values in the population. Must be non-negative.
|
|
fixed64 count = 4;
|
|
|
|
// sum of the values in the population. If count is zero then this field
|
|
// must be zero.
|
|
//
|
|
// Note: Sum should only be filled out when measuring non-negative discrete
|
|
// events, and is assumed to be monotonic over the values of these events.
|
|
// Negative events *can* be recorded, but sum should not be filled out when
|
|
// doing so. This is specifically to enforce compatibility w/ OpenMetrics,
|
|
// see: https://github.com/OpenObservability/OpenMetrics/blob/main/specification/OpenMetrics.md#summary
|
|
double sum = 5;
|
|
|
|
// Represents the value at a given quantile of a distribution.
|
|
//
|
|
// To record Min and Max values following conventions are used:
|
|
// - The 1.0 quantile is equivalent to the maximum value observed.
|
|
// - The 0.0 quantile is equivalent to the minimum value observed.
|
|
//
|
|
// See the following issue for more context:
|
|
// https://github.com/open-telemetry/opentelemetry-proto/issues/125
|
|
message ValueAtQuantile {
|
|
// The quantile of a distribution. Must be in the interval
|
|
// [0.0, 1.0].
|
|
double quantile = 1;
|
|
|
|
// The value at the given quantile of a distribution.
|
|
//
|
|
// Quantile values must NOT be negative.
|
|
double value = 2;
|
|
}
|
|
|
|
// (Optional) list of values at different quantiles of the distribution calculated
|
|
// from the current snapshot. The quantiles must be strictly increasing.
|
|
repeated ValueAtQuantile quantile_values = 6;
|
|
|
|
// Flags that apply to this specific data point. See DataPointFlags
|
|
// for the available flags and their meaning.
|
|
uint32 flags = 8;
|
|
}
|
|
|
|
// A representation of an exemplar, which is a sample input measurement.
|
|
// Exemplars also hold information about the environment when the measurement
|
|
// was recorded, for example the span and trace ID of the active span when the
|
|
// exemplar was recorded.
|
|
message Exemplar {
|
|
reserved 1;
|
|
|
|
// The set of key/value pairs that were filtered out by the aggregator, but
|
|
// recorded alongside the original measurement. Only key/value pairs that were
|
|
// filtered out by the aggregator should be included
|
|
repeated KeyValue filtered_attributes = 7;
|
|
|
|
// time_unix_nano is the exact time when this exemplar was recorded
|
|
//
|
|
// Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January
|
|
// 1970.
|
|
fixed64 time_unix_nano = 2;
|
|
|
|
// The value of the measurement that was recorded. An exemplar is
|
|
// considered invalid when one of the recognized value fields is not present
|
|
// inside this oneof.
|
|
oneof value {
|
|
double as_double = 3;
|
|
sfixed64 as_int = 6;
|
|
}
|
|
|
|
// (Optional) Span ID of the exemplar trace.
|
|
// span_id may be missing if the measurement is not recorded inside a trace
|
|
// or if the trace is not sampled.
|
|
bytes span_id = 4;
|
|
|
|
// (Optional) Trace ID of the exemplar trace.
|
|
// trace_id may be missing if the measurement is not recorded inside a trace
|
|
// or if the trace is not sampled.
|
|
bytes trace_id = 5;
|
|
}
|