// Copyright 2019 Google LLC. // // 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.api; import "google/protobuf/any.proto"; import "google/protobuf/timestamp.proto"; option go_package = "google.golang.org/genproto/googleapis/api/distribution;distribution"; option java_multiple_files = true; option java_outer_classname = "DistributionProto"; option java_package = "com.google.api"; option objc_class_prefix = "GAPI"; // `Distribution` contains summary statistics for a population of values. It // optionally contains a histogram representing the distribution of those values // across a set of buckets. // // The summary statistics are the count, mean, sum of the squared deviation from // the mean, the minimum, and the maximum of the set of population of values. // The histogram is based on a sequence of buckets and gives a count of values // that fall into each bucket. The boundaries of the buckets are given either // explicitly or by formulas for buckets of fixed or exponentially increasing // widths. // // Although it is not forbidden, it is generally a bad idea to include // non-finite values (infinities or NaNs) in the population of values, as this // will render the `mean` and `sum_of_squared_deviation` fields meaningless. message Distribution { // The range of the population values. message Range { // The minimum of the population values. double min = 1; // The maximum of the population values. double max = 2; } // `BucketOptions` describes the bucket boundaries used to create a histogram // for the distribution. The buckets can be in a linear sequence, an // exponential sequence, or each bucket can be specified explicitly. // `BucketOptions` does not include the number of values in each bucket. // // A bucket has an inclusive lower bound and exclusive upper bound for the // values that are counted for that bucket. The upper bound of a bucket must // be strictly greater than the lower bound. The sequence of N buckets for a // distribution consists of an underflow bucket (number 0), zero or more // finite buckets (number 1 through N - 2) and an overflow bucket (number N - // 1). The buckets are contiguous: the lower bound of bucket i (i > 0) is the // same as the upper bound of bucket i - 1. The buckets span the whole range // of finite values: lower bound of the underflow bucket is -infinity and the // upper bound of the overflow bucket is +infinity. The finite buckets are // so-called because both bounds are finite. message BucketOptions { // Specifies a linear sequence of buckets that all have the same width // (except overflow and underflow). Each bucket represents a constant // absolute uncertainty on the specific value in the bucket. // // There are `num_finite_buckets + 2` (= N) buckets. Bucket `i` has the // following boundaries: // // Upper bound (0 <= i < N-1): offset + (width * i). // Lower bound (1 <= i < N): offset + (width * (i - 1)). message Linear { // Must be greater than 0. int32 num_finite_buckets = 1; // Must be greater than 0. double width = 2; // Lower bound of the first bucket. double offset = 3; } // Specifies an exponential sequence of buckets that have a width that is // proportional to the value of the lower bound. Each bucket represents a // constant relative uncertainty on a specific value in the bucket. // // There are `num_finite_buckets + 2` (= N) buckets. Bucket `i` has the // following boundaries: // // Upper bound (0 <= i < N-1): scale * (growth_factor ^ i). // Lower bound (1 <= i < N): scale * (growth_factor ^ (i - 1)). message Exponential { // Must be greater than 0. int32 num_finite_buckets = 1; // Must be greater than 1. double growth_factor = 2; // Must be greater than 0. double scale = 3; } // Specifies a set of buckets with arbitrary widths. // // There are `size(bounds) + 1` (= N) buckets. Bucket `i` has the following // boundaries: // // Upper bound (0 <= i < N-1): bounds[i] // Lower bound (1 <= i < N); bounds[i - 1] // // The `bounds` field must contain at least one element. If `bounds` has // only one element, then there are no finite buckets, and that single // element is the common boundary of the overflow and underflow buckets. message Explicit { // The values must be monotonically increasing. repeated double bounds = 1; } // Exactly one of these three fields must be set. oneof options { // The linear bucket. Linear linear_buckets = 1; // The exponential buckets. Exponential exponential_buckets = 2; // The explicit buckets. Explicit explicit_buckets = 3; } } // Exemplars are example points that may be used to annotate aggregated // distribution values. They are metadata that gives information about a // particular value added to a Distribution bucket, such as a trace ID that // was active when a value was added. They may contain further information, // such as a example values and timestamps, origin, etc. message Exemplar { // Value of the exemplar point. This value determines to which bucket the // exemplar belongs. double value = 1; // The observation (sampling) time of the above value. google.protobuf.Timestamp timestamp = 2; // Contextual information about the example value. Examples are: // // Trace: type.googleapis.com/google.monitoring.v3.SpanContext // // Literal string: type.googleapis.com/google.protobuf.StringValue // // Labels dropped during aggregation: // type.googleapis.com/google.monitoring.v3.DroppedLabels // // There may be only a single attachment of any given message type in a // single exemplar, and this is enforced by the system. repeated google.protobuf.Any attachments = 3; } // The number of values in the population. Must be non-negative. This value // must equal the sum of the values in `bucket_counts` if a histogram is // provided. int64 count = 1; // The arithmetic mean of the values in the population. If `count` is zero // then this field must be zero. double mean = 2; // The sum of squared deviations from the mean of the values in the // population. For values x_i this is: // // Sum[i=1..n]((x_i - mean)^2) // // Knuth, "The Art of Computer Programming", Vol. 2, page 323, 3rd edition // describes Welford's method for accumulating this sum in one pass. // // If `count` is zero then this field must be zero. double sum_of_squared_deviation = 3; // If specified, contains the range of the population values. The field // must not be present if the `count` is zero. Range range = 4; // Defines the histogram bucket boundaries. If the distribution does not // contain a histogram, then omit this field. BucketOptions bucket_options = 6; // The number of values in each bucket of the histogram, as described in // `bucket_options`. If the distribution does not have a histogram, then omit // this field. If there is a histogram, then the sum of the values in // `bucket_counts` must equal the value in the `count` field of the // distribution. // // If present, `bucket_counts` should contain N values, where N is the number // of buckets specified in `bucket_options`. If you supply fewer than N // values, the remaining values are assumed to be 0. // // The order of the values in `bucket_counts` follows the bucket numbering // schemes described for the three bucket types. The first value must be the // count for the underflow bucket (number 0). The next N-2 values are the // counts for the finite buckets (number 1 through N-2). The N'th value in // `bucket_counts` is the count for the overflow bucket (number N-1). repeated int64 bucket_counts = 7; // Must be in increasing order of `value` field. repeated Exemplar exemplars = 10; }