// Copyright 2016 Google Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
syntax = "proto3";
package google.monitoring.v3;
import "google/api/distribution.proto";
import "google/protobuf/duration.proto";
import "google/protobuf/timestamp.proto";
option csharp_namespace = "Google.Cloud.Monitoring.V3";
option go_package = "google.golang.org/genproto/googleapis/monitoring/v3;monitoring";
option java_multiple_files = true;
option java_outer_classname = "CommonProto";
option java_package = "com.google.monitoring.v3";
// A single strongly-typed value.
message TypedValue {
// The typed value field.
oneof value {
// A Boolean value: `true` or `false`.
bool bool_value = 1;
// A 64-bit integer. Its range is approximately ±9.2x1018.
int64 int64_value = 2;
// A 64-bit double-precision floating-point number. Its magnitude
// is approximately ±10±300 and it has 16
// significant digits of precision.
double double_value = 3;
// A variable-length string value.
string string_value = 4;
// A distribution value.
google.api.Distribution distribution_value = 5;
}
}
// A time interval extending just after a start time through an end time.
// If the start time is the same as the end time, then the interval
// represents a single point in time.
message TimeInterval {
// Required. The end of the time interval.
google.protobuf.Timestamp end_time = 2;
// Optional. The beginning of the time interval. The default value
// for the start time is the end time. The start time must not be
// later than the end time.
google.protobuf.Timestamp start_time = 1;
}
// Describes how to combine multiple time series to provide different views of
// the data. Aggregation consists of an alignment step on individual time
// series (`per_series_aligner`) followed by an optional reduction of the data
// across different time series (`cross_series_reducer`). For more details, see
// [Aggregation](/monitoring/api/learn_more#aggregation).
message Aggregation {
// The Aligner describes how to bring the data points in a single
// time series into temporal alignment.
enum Aligner {
// No alignment. Raw data is returned. Not valid if cross-time
// series reduction is requested. The value type of the result is
// the same as the value type of the input.
ALIGN_NONE = 0;
// Align and convert to delta metric type. This alignment is valid
// for cumulative metrics and delta metrics. Aligning an existing
// delta metric to a delta metric requires that the alignment
// period be increased. The value type of the result is the same
// as the value type of the input.
ALIGN_DELTA = 1;
// Align and convert to a rate. This alignment is valid for
// cumulative metrics and delta metrics with numeric values. The output is a
// gauge metric with value type
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE].
ALIGN_RATE = 2;
// Align by interpolating between adjacent points around the
// period boundary. This alignment is valid for gauge
// metrics with numeric values. The value type of the result is the same
// as the value type of the input.
ALIGN_INTERPOLATE = 3;
// Align by shifting the oldest data point before the period
// boundary to the boundary. This alignment is valid for gauge
// metrics. The value type of the result is the same as the
// value type of the input.
ALIGN_NEXT_OLDER = 4;
// Align time series via aggregation. The resulting data point in
// the alignment period is the minimum of all data points in the
// period. This alignment is valid for gauge and delta metrics with numeric
// values. The value type of the result is the same as the value
// type of the input.
ALIGN_MIN = 10;
// Align time series via aggregation. The resulting data point in
// the alignment period is the maximum of all data points in the
// period. This alignment is valid for gauge and delta metrics with numeric
// values. The value type of the result is the same as the value
// type of the input.
ALIGN_MAX = 11;
// Align time series via aggregation. The resulting data point in
// the alignment period is the average or arithmetic mean of all
// data points in the period. This alignment is valid for gauge and delta
// metrics with numeric values. The value type of the output is
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE].
ALIGN_MEAN = 12;
// Align time series via aggregation. The resulting data point in
// the alignment period is the count of all data points in the
// period. This alignment is valid for gauge and delta metrics with numeric
// or Boolean values. The value type of the output is
// [INT64][google.api.MetricDescriptor.ValueType.INT64].
ALIGN_COUNT = 13;
// Align time series via aggregation. The resulting data point in
// the alignment period is the sum of all data points in the
// period. This alignment is valid for gauge and delta metrics with numeric
// and distribution values. The value type of the output is the
// same as the value type of the input.
ALIGN_SUM = 14;
// Align time series via aggregation. The resulting data point in
// the alignment period is the standard deviation of all data
// points in the period. This alignment is valid for gauge and delta metrics
// with numeric values. The value type of the output is
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE].
ALIGN_STDDEV = 15;
// Align time series via aggregation. The resulting data point in
// the alignment period is the count of True-valued data points in the
// period. This alignment is valid for gauge metrics with
// Boolean values. The value type of the output is
// [INT64][google.api.MetricDescriptor.ValueType.INT64].
ALIGN_COUNT_TRUE = 16;
// Align time series via aggregation. The resulting data point in
// the alignment period is the fraction of True-valued data points in the
// period. This alignment is valid for gauge metrics with Boolean values.
// The output value is in the range [0, 1] and has value type
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE].
ALIGN_FRACTION_TRUE = 17;
// Align time series via aggregation. The resulting data point in
// the alignment period is the 99th percentile of all data
// points in the period. This alignment is valid for gauge and delta metrics
// with distribution values. The output is a gauge metric with value type
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE].
ALIGN_PERCENTILE_99 = 18;
// Align time series via aggregation. The resulting data point in
// the alignment period is the 95th percentile of all data
// points in the period. This alignment is valid for gauge and delta metrics
// with distribution values. The output is a gauge metric with value type
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE].
ALIGN_PERCENTILE_95 = 19;
// Align time series via aggregation. The resulting data point in
// the alignment period is the 50th percentile of all data
// points in the period. This alignment is valid for gauge and delta metrics
// with distribution values. The output is a gauge metric with value type
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE].
ALIGN_PERCENTILE_50 = 20;
// Align time series via aggregation. The resulting data point in
// the alignment period is the 5th percentile of all data
// points in the period. This alignment is valid for gauge and delta metrics
// with distribution values. The output is a gauge metric with value type
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE].
ALIGN_PERCENTILE_05 = 21;
}
// A Reducer describes how to aggregate data points from multiple
// time series into a single time series.
enum Reducer {
// No cross-time series reduction. The output of the aligner is
// returned.
REDUCE_NONE = 0;
// Reduce by computing the mean across time series for each
// alignment period. This reducer is valid for delta and
// gauge metrics with numeric or distribution values. The value type of the
// output is [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE].
REDUCE_MEAN = 1;
// Reduce by computing the minimum across time series for each
// alignment period. This reducer is valid for delta and
// gauge metrics with numeric values. The value type of the output
// is the same as the value type of the input.
REDUCE_MIN = 2;
// Reduce by computing the maximum across time series for each
// alignment period. This reducer is valid for delta and
// gauge metrics with numeric values. The value type of the output
// is the same as the value type of the input.
REDUCE_MAX = 3;
// Reduce by computing the sum across time series for each
// alignment period. This reducer is valid for delta and
// gauge metrics with numeric and distribution values. The value type of
// the output is the same as the value type of the input.
REDUCE_SUM = 4;
// Reduce by computing the standard deviation across time series
// for each alignment period. This reducer is valid for delta
// and gauge metrics with numeric or distribution values. The value type of
// the output is [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE].
REDUCE_STDDEV = 5;
// Reduce by computing the count of data points across time series
// for each alignment period. This reducer is valid for delta
// and gauge metrics of numeric, Boolean, distribution, and string value
// type. The value type of the output is
// [INT64][google.api.MetricDescriptor.ValueType.INT64].
REDUCE_COUNT = 6;
// Reduce by computing the count of True-valued data points across time
// series for each alignment period. This reducer is valid for delta
// and gauge metrics of Boolean value type. The value type of
// the output is [INT64][google.api.MetricDescriptor.ValueType.INT64].
REDUCE_COUNT_TRUE = 7;
// Reduce by computing the fraction of True-valued data points across time
// series for each alignment period. This reducer is valid for delta
// and gauge metrics of Boolean value type. The output value is in the
// range [0, 1] and has value type
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE].
REDUCE_FRACTION_TRUE = 8;
// Reduce by computing 99th percentile of data points across time series
// for each alignment period. This reducer is valid for gauge and delta
// metrics of numeric and distribution type. The value of the output is
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE]
REDUCE_PERCENTILE_99 = 9;
// Reduce by computing 95th percentile of data points across time series
// for each alignment period. This reducer is valid for gauge and delta
// metrics of numeric and distribution type. The value of the output is
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE]
REDUCE_PERCENTILE_95 = 10;
// Reduce by computing 50th percentile of data points across time series
// for each alignment period. This reducer is valid for gauge and delta
// metrics of numeric and distribution type. The value of the output is
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE]
REDUCE_PERCENTILE_50 = 11;
// Reduce by computing 5th percentile of data points across time series
// for each alignment period. This reducer is valid for gauge and delta
// metrics of numeric and distribution type. The value of the output is
// [DOUBLE][google.api.MetricDescriptor.ValueType.DOUBLE]
REDUCE_PERCENTILE_05 = 12;
}
// The alignment period for per-[time series][google.monitoring.v3.TimeSeries]
// alignment. If present, `alignmentPeriod` must be at least 60
// seconds. After per-time series alignment, each time series will
// contain data points only on the period boundaries. If
// `perSeriesAligner` is not specified or equals `ALIGN_NONE`, then
// this field is ignored. If `perSeriesAligner` is specified and
// does not equal `ALIGN_NONE`, then this field must be defined;
// otherwise an error is returned.
google.protobuf.Duration alignment_period = 1;
// The approach to be used to align individual time series. Not all
// alignment functions may be applied to all time series, depending
// on the metric type and value type of the original time
// series. Alignment may change the metric type or the value type of
// the time series.
//
// Time series data must be aligned in order to perform cross-time
// series reduction. If `crossSeriesReducer` is specified, then
// `perSeriesAligner` must be specified and not equal `ALIGN_NONE`
// and `alignmentPeriod` must be specified; otherwise, an error is
// returned.
Aligner per_series_aligner = 2;
// The approach to be used to combine time series. Not all reducer
// functions may be applied to all time series, depending on the
// metric type and the value type of the original time
// series. Reduction may change the metric type of value type of the
// time series.
//
// Time series data must be aligned in order to perform cross-time
// series reduction. If `crossSeriesReducer` is specified, then
// `perSeriesAligner` must be specified and not equal `ALIGN_NONE`
// and `alignmentPeriod` must be specified; otherwise, an error is
// returned.
Reducer cross_series_reducer = 4;
// The set of fields to preserve when `crossSeriesReducer` is
// specified. The `groupByFields` determine how the time series are
// partitioned into subsets prior to applying the aggregation
// function. Each subset contains time series that have the same
// value for each of the grouping fields. Each individual time
// series is a member of exactly one subset. The
// `crossSeriesReducer` is applied to each subset of time series.
// It is not possible to reduce across different resource types, so
// this field implicitly contains `resource.type`. Fields not
// specified in `groupByFields` are aggregated away. If
// `groupByFields` is not specified and all the time series have
// the same resource type, then the time series are aggregated into
// a single output time series. If `crossSeriesReducer` is not
// defined, this field is ignored.
repeated string group_by_fields = 5;
}