google-api-ruby-client/generated/google/apis/toolresults_v1beta3/classes.rb

2753 lines
130 KiB
Ruby

# Copyright 2015 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.
require 'date'
require 'google/apis/core/base_service'
require 'google/apis/core/json_representation'
require 'google/apis/core/hashable'
require 'google/apis/errors'
module Google
module Apis
module ToolresultsV1beta3
# Android app information.
class AndroidAppInfo
include Google::Apis::Core::Hashable
# The name of the app. Optional
# Corresponds to the JSON property `name`
# @return [String]
attr_accessor :name
# The package name of the app. Required.
# Corresponds to the JSON property `packageName`
# @return [String]
attr_accessor :package_name
# The internal version code of the app. Optional.
# Corresponds to the JSON property `versionCode`
# @return [String]
attr_accessor :version_code
# The version name of the app. Optional.
# Corresponds to the JSON property `versionName`
# @return [String]
attr_accessor :version_name
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@name = args[:name] if args.key?(:name)
@package_name = args[:package_name] if args.key?(:package_name)
@version_code = args[:version_code] if args.key?(:version_code)
@version_name = args[:version_name] if args.key?(:version_name)
end
end
# A test of an Android application that can control an Android component
# independently of its normal lifecycle.
# See for more information on types of Android tests.
class AndroidInstrumentationTest
include Google::Apis::Core::Hashable
# The java package for the test to be executed. Required
# Corresponds to the JSON property `testPackageId`
# @return [String]
attr_accessor :test_package_id
# The InstrumentationTestRunner class. Required
# Corresponds to the JSON property `testRunnerClass`
# @return [String]
attr_accessor :test_runner_class
# Each target must be fully qualified with the package name or class name, in
# one of these formats: - "package package_name" - "class package_name.
# class_name" - "class package_name.class_name#method_name"
# If empty, all targets in the module will be run.
# Corresponds to the JSON property `testTargets`
# @return [Array<String>]
attr_accessor :test_targets
# The flag indicates whether Android Test Orchestrator will be used to run test
# or not.
# Corresponds to the JSON property `useOrchestrator`
# @return [Boolean]
attr_accessor :use_orchestrator
alias_method :use_orchestrator?, :use_orchestrator
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@test_package_id = args[:test_package_id] if args.key?(:test_package_id)
@test_runner_class = args[:test_runner_class] if args.key?(:test_runner_class)
@test_targets = args[:test_targets] if args.key?(:test_targets)
@use_orchestrator = args[:use_orchestrator] if args.key?(:use_orchestrator)
end
end
# A test of an android application that explores the application on a virtual or
# physical Android device, finding culprits and crashes as it goes.
class AndroidRoboTest
include Google::Apis::Core::Hashable
# The initial activity that should be used to start the app. Optional
# Corresponds to the JSON property `appInitialActivity`
# @return [String]
attr_accessor :app_initial_activity
# The java package for the bootstrap. Optional
# Corresponds to the JSON property `bootstrapPackageId`
# @return [String]
attr_accessor :bootstrap_package_id
# The runner class for the bootstrap. Optional
# Corresponds to the JSON property `bootstrapRunnerClass`
# @return [String]
attr_accessor :bootstrap_runner_class
# The max depth of the traversal stack Robo can explore. Optional
# Corresponds to the JSON property `maxDepth`
# @return [Fixnum]
attr_accessor :max_depth
# The max number of steps/actions Robo can execute. Default is no limit (0).
# Optional
# Corresponds to the JSON property `maxSteps`
# @return [Fixnum]
attr_accessor :max_steps
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@app_initial_activity = args[:app_initial_activity] if args.key?(:app_initial_activity)
@bootstrap_package_id = args[:bootstrap_package_id] if args.key?(:bootstrap_package_id)
@bootstrap_runner_class = args[:bootstrap_runner_class] if args.key?(:bootstrap_runner_class)
@max_depth = args[:max_depth] if args.key?(:max_depth)
@max_steps = args[:max_steps] if args.key?(:max_steps)
end
end
# An Android mobile test specification.
class AndroidTest
include Google::Apis::Core::Hashable
# Android app information.
# Corresponds to the JSON property `androidAppInfo`
# @return [Google::Apis::ToolresultsV1beta3::AndroidAppInfo]
attr_accessor :android_app_info
# A test of an Android application that can control an Android component
# independently of its normal lifecycle.
# See for more information on types of Android tests.
# Corresponds to the JSON property `androidInstrumentationTest`
# @return [Google::Apis::ToolresultsV1beta3::AndroidInstrumentationTest]
attr_accessor :android_instrumentation_test
# A test of an android application that explores the application on a virtual or
# physical Android device, finding culprits and crashes as it goes.
# Corresponds to the JSON property `androidRoboTest`
# @return [Google::Apis::ToolresultsV1beta3::AndroidRoboTest]
attr_accessor :android_robo_test
# A Duration represents a signed, fixed-length span of time represented as a
# count of seconds and fractions of seconds at nanosecond resolution. It is
# independent of any calendar and concepts like "day" or "month". It is related
# to Timestamp in that the difference between two Timestamp values is a Duration
# and it can be added or subtracted from a Timestamp. Range is approximately +-
# 10,000 years.
# # Examples
# Example 1: Compute Duration from two Timestamps in pseudo code.
# Timestamp start = ...; Timestamp end = ...; Duration duration = ...;
# duration.seconds = end.seconds - start.seconds; duration.nanos = end.nanos -
# start.nanos;
# if (duration.seconds 0) ` duration.seconds += 1; duration.nanos -= 1000000000;
# ` else if (durations.seconds > 0 && duration.nanos < 0) ` duration.seconds -=
# 1; duration.nanos += 1000000000; `
# Example 2: Compute Timestamp from Timestamp + Duration in pseudo code.
# Timestamp start = ...; Duration duration = ...; Timestamp end = ...;
# end.seconds = start.seconds + duration.seconds; end.nanos = start.nanos +
# duration.nanos;
# if (end.nanos = 1000000000) ` end.seconds += 1; end.nanos -= 1000000000; `
# Example 3: Compute Duration from datetime.timedelta in Python.
# td = datetime.timedelta(days=3, minutes=10) duration = Duration() duration.
# FromTimedelta(td)
# # JSON Mapping
# In JSON format, the Duration type is encoded as a string rather than an object,
# where the string ends in the suffix "s" (indicating seconds) and is preceded
# by the number of seconds, with nanoseconds expressed as fractional seconds.
# For example, 3 seconds with 0 nanoseconds should be encoded in JSON format as "
# 3s", while 3 seconds and 1 nanosecond should be expressed in JSON format as "3.
# 000000001s", and 3 seconds and 1 microsecond should be expressed in JSON
# format as "3.000001s".
# Corresponds to the JSON property `testTimeout`
# @return [Google::Apis::ToolresultsV1beta3::Duration]
attr_accessor :test_timeout
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@android_app_info = args[:android_app_info] if args.key?(:android_app_info)
@android_instrumentation_test = args[:android_instrumentation_test] if args.key?(:android_instrumentation_test)
@android_robo_test = args[:android_robo_test] if args.key?(:android_robo_test)
@test_timeout = args[:test_timeout] if args.key?(:test_timeout)
end
end
# `Any` contains an arbitrary serialized protocol buffer message along with a
# URL that describes the type of the serialized message.
# Protobuf library provides support to pack/unpack Any values in the form of
# utility functions or additional generated methods of the Any type.
# Example 1: Pack and unpack a message in C++.
# Foo foo = ...; Any any; any.PackFrom(foo); ... if (any.UnpackTo(&foo)) ` ... `
# Example 2: Pack and unpack a message in Java.
# Foo foo = ...; Any any = Any.pack(foo); ... if (any.is(Foo.class)) ` foo = any.
# unpack(Foo.class); `
# Example 3: Pack and unpack a message in Python.
# foo = Foo(...) any = Any() any.Pack(foo) ... if any.Is(Foo.DESCRIPTOR): any.
# Unpack(foo) ...
# Example 4: Pack and unpack a message in Go
# foo := &pb.Foo`...` any, err := ptypes.MarshalAny(foo) ... foo := &pb.Foo`` if
# err := ptypes.UnmarshalAny(any, foo); err != nil ` ... `
# The pack methods provided by protobuf library will by default use 'type.
# googleapis.com/full.type.name' as the type URL and the unpack methods only use
# the fully qualified type name after the last '/' in the type URL, for example "
# foo.bar.com/x/y.z" will yield type name "y.z".
# JSON ==== The JSON representation of an `Any` value uses the regular
# representation of the deserialized, embedded message, with an additional field
# `@type` which contains the type URL. Example:
# package google.profile; message Person ` string first_name = 1; string
# last_name = 2; `
# ` "@type": "type.googleapis.com/google.profile.Person", "firstName": , "
# lastName": `
# If the embedded message type is well-known and has a custom JSON
# representation, that representation will be embedded adding a field `value`
# which holds the custom JSON in addition to the `@type` field. Example (for
# message [google.protobuf.Duration][]):
# ` "@type": "type.googleapis.com/google.protobuf.Duration", "value": "1.212s" `
class Any
include Google::Apis::Core::Hashable
# A URL/resource name that uniquely identifies the type of the serialized
# protocol buffer message. The last segment of the URL's path must represent the
# fully qualified name of the type (as in `path/google.protobuf.Duration`). The
# name should be in a canonical form (e.g., leading "." is not accepted).
# In practice, teams usually precompile into the binary all types that they
# expect it to use in the context of Any. However, for URLs which use the scheme
# `http`, `https`, or no scheme, one can optionally set up a type server that
# maps type URLs to message definitions as follows:
# * If no scheme is provided, `https` is assumed. * An HTTP GET on the URL must
# yield a [google.protobuf.Type][] value in binary format, or produce an error. *
# Applications are allowed to cache lookup results based on the URL, or have
# them precompiled into a binary to avoid any lookup. Therefore, binary
# compatibility needs to be preserved on changes to types. (Use versioned type
# names to manage breaking changes.)
# Note: this functionality is not currently available in the official protobuf
# release, and it is not used for type URLs beginning with type.googleapis.com.
# Schemes other than `http`, `https` (or the empty scheme) might be used with
# implementation specific semantics.
# Corresponds to the JSON property `typeUrl`
# @return [String]
attr_accessor :type_url
# Must be a valid serialized protocol buffer of the above specified type.
# Corresponds to the JSON property `value`
# NOTE: Values are automatically base64 encoded/decoded in the client library.
# @return [String]
attr_accessor :value
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@type_url = args[:type_url] if args.key?(:type_url)
@value = args[:value] if args.key?(:value)
end
end
#
class AppStartTime
include Google::Apis::Core::Hashable
# A Duration represents a signed, fixed-length span of time represented as a
# count of seconds and fractions of seconds at nanosecond resolution. It is
# independent of any calendar and concepts like "day" or "month". It is related
# to Timestamp in that the difference between two Timestamp values is a Duration
# and it can be added or subtracted from a Timestamp. Range is approximately +-
# 10,000 years.
# # Examples
# Example 1: Compute Duration from two Timestamps in pseudo code.
# Timestamp start = ...; Timestamp end = ...; Duration duration = ...;
# duration.seconds = end.seconds - start.seconds; duration.nanos = end.nanos -
# start.nanos;
# if (duration.seconds 0) ` duration.seconds += 1; duration.nanos -= 1000000000;
# ` else if (durations.seconds > 0 && duration.nanos < 0) ` duration.seconds -=
# 1; duration.nanos += 1000000000; `
# Example 2: Compute Timestamp from Timestamp + Duration in pseudo code.
# Timestamp start = ...; Duration duration = ...; Timestamp end = ...;
# end.seconds = start.seconds + duration.seconds; end.nanos = start.nanos +
# duration.nanos;
# if (end.nanos = 1000000000) ` end.seconds += 1; end.nanos -= 1000000000; `
# Example 3: Compute Duration from datetime.timedelta in Python.
# td = datetime.timedelta(days=3, minutes=10) duration = Duration() duration.
# FromTimedelta(td)
# # JSON Mapping
# In JSON format, the Duration type is encoded as a string rather than an object,
# where the string ends in the suffix "s" (indicating seconds) and is preceded
# by the number of seconds, with nanoseconds expressed as fractional seconds.
# For example, 3 seconds with 0 nanoseconds should be encoded in JSON format as "
# 3s", while 3 seconds and 1 nanosecond should be expressed in JSON format as "3.
# 000000001s", and 3 seconds and 1 microsecond should be expressed in JSON
# format as "3.000001s".
# Corresponds to the JSON property `fullyDrawnTime`
# @return [Google::Apis::ToolresultsV1beta3::Duration]
attr_accessor :fully_drawn_time
# A Duration represents a signed, fixed-length span of time represented as a
# count of seconds and fractions of seconds at nanosecond resolution. It is
# independent of any calendar and concepts like "day" or "month". It is related
# to Timestamp in that the difference between two Timestamp values is a Duration
# and it can be added or subtracted from a Timestamp. Range is approximately +-
# 10,000 years.
# # Examples
# Example 1: Compute Duration from two Timestamps in pseudo code.
# Timestamp start = ...; Timestamp end = ...; Duration duration = ...;
# duration.seconds = end.seconds - start.seconds; duration.nanos = end.nanos -
# start.nanos;
# if (duration.seconds 0) ` duration.seconds += 1; duration.nanos -= 1000000000;
# ` else if (durations.seconds > 0 && duration.nanos < 0) ` duration.seconds -=
# 1; duration.nanos += 1000000000; `
# Example 2: Compute Timestamp from Timestamp + Duration in pseudo code.
# Timestamp start = ...; Duration duration = ...; Timestamp end = ...;
# end.seconds = start.seconds + duration.seconds; end.nanos = start.nanos +
# duration.nanos;
# if (end.nanos = 1000000000) ` end.seconds += 1; end.nanos -= 1000000000; `
# Example 3: Compute Duration from datetime.timedelta in Python.
# td = datetime.timedelta(days=3, minutes=10) duration = Duration() duration.
# FromTimedelta(td)
# # JSON Mapping
# In JSON format, the Duration type is encoded as a string rather than an object,
# where the string ends in the suffix "s" (indicating seconds) and is preceded
# by the number of seconds, with nanoseconds expressed as fractional seconds.
# For example, 3 seconds with 0 nanoseconds should be encoded in JSON format as "
# 3s", while 3 seconds and 1 nanosecond should be expressed in JSON format as "3.
# 000000001s", and 3 seconds and 1 microsecond should be expressed in JSON
# format as "3.000001s".
# Corresponds to the JSON property `initialDisplayTime`
# @return [Google::Apis::ToolresultsV1beta3::Duration]
attr_accessor :initial_display_time
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@fully_drawn_time = args[:fully_drawn_time] if args.key?(:fully_drawn_time)
@initial_display_time = args[:initial_display_time] if args.key?(:initial_display_time)
end
end
# Encapsulates the metadata for basic sample series represented by a line chart
class BasicPerfSampleSeries
include Google::Apis::Core::Hashable
#
# Corresponds to the JSON property `perfMetricType`
# @return [String]
attr_accessor :perf_metric_type
#
# Corresponds to the JSON property `perfUnit`
# @return [String]
attr_accessor :perf_unit
#
# Corresponds to the JSON property `sampleSeriesLabel`
# @return [String]
attr_accessor :sample_series_label
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@perf_metric_type = args[:perf_metric_type] if args.key?(:perf_metric_type)
@perf_unit = args[:perf_unit] if args.key?(:perf_unit)
@sample_series_label = args[:sample_series_label] if args.key?(:sample_series_label)
end
end
# The request must provide up to a maximum of 5000 samples to be created; a
# larger sample size will cause an INVALID_ARGUMENT error
class BatchCreatePerfSamplesRequest
include Google::Apis::Core::Hashable
# The set of PerfSamples to create should not include existing timestamps
# Corresponds to the JSON property `perfSamples`
# @return [Array<Google::Apis::ToolresultsV1beta3::PerfSample>]
attr_accessor :perf_samples
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@perf_samples = args[:perf_samples] if args.key?(:perf_samples)
end
end
#
class BatchCreatePerfSamplesResponse
include Google::Apis::Core::Hashable
#
# Corresponds to the JSON property `perfSamples`
# @return [Array<Google::Apis::ToolresultsV1beta3::PerfSample>]
attr_accessor :perf_samples
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@perf_samples = args[:perf_samples] if args.key?(:perf_samples)
end
end
#
class CpuInfo
include Google::Apis::Core::Hashable
# description of the device processor ie '1.8 GHz hexa core 64-bit ARMv8-A'
# Corresponds to the JSON property `cpuProcessor`
# @return [String]
attr_accessor :cpu_processor
# the CPU clock speed in GHz
# Corresponds to the JSON property `cpuSpeedInGhz`
# @return [Float]
attr_accessor :cpu_speed_in_ghz
# the number of CPU cores
# Corresponds to the JSON property `numberOfCores`
# @return [Fixnum]
attr_accessor :number_of_cores
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@cpu_processor = args[:cpu_processor] if args.key?(:cpu_processor)
@cpu_speed_in_ghz = args[:cpu_speed_in_ghz] if args.key?(:cpu_speed_in_ghz)
@number_of_cores = args[:number_of_cores] if args.key?(:number_of_cores)
end
end
# A Duration represents a signed, fixed-length span of time represented as a
# count of seconds and fractions of seconds at nanosecond resolution. It is
# independent of any calendar and concepts like "day" or "month". It is related
# to Timestamp in that the difference between two Timestamp values is a Duration
# and it can be added or subtracted from a Timestamp. Range is approximately +-
# 10,000 years.
# # Examples
# Example 1: Compute Duration from two Timestamps in pseudo code.
# Timestamp start = ...; Timestamp end = ...; Duration duration = ...;
# duration.seconds = end.seconds - start.seconds; duration.nanos = end.nanos -
# start.nanos;
# if (duration.seconds 0) ` duration.seconds += 1; duration.nanos -= 1000000000;
# ` else if (durations.seconds > 0 && duration.nanos < 0) ` duration.seconds -=
# 1; duration.nanos += 1000000000; `
# Example 2: Compute Timestamp from Timestamp + Duration in pseudo code.
# Timestamp start = ...; Duration duration = ...; Timestamp end = ...;
# end.seconds = start.seconds + duration.seconds; end.nanos = start.nanos +
# duration.nanos;
# if (end.nanos = 1000000000) ` end.seconds += 1; end.nanos -= 1000000000; `
# Example 3: Compute Duration from datetime.timedelta in Python.
# td = datetime.timedelta(days=3, minutes=10) duration = Duration() duration.
# FromTimedelta(td)
# # JSON Mapping
# In JSON format, the Duration type is encoded as a string rather than an object,
# where the string ends in the suffix "s" (indicating seconds) and is preceded
# by the number of seconds, with nanoseconds expressed as fractional seconds.
# For example, 3 seconds with 0 nanoseconds should be encoded in JSON format as "
# 3s", while 3 seconds and 1 nanosecond should be expressed in JSON format as "3.
# 000000001s", and 3 seconds and 1 microsecond should be expressed in JSON
# format as "3.000001s".
class Duration
include Google::Apis::Core::Hashable
# Signed fractions of a second at nanosecond resolution of the span of time.
# Durations less than one second are represented with a 0 `seconds` field and a
# positive or negative `nanos` field. For durations of one second or more, a non-
# zero value for the `nanos` field must be of the same sign as the `seconds`
# field. Must be from -999,999,999 to +999,999,999 inclusive.
# Corresponds to the JSON property `nanos`
# @return [Fixnum]
attr_accessor :nanos
# Signed seconds of the span of time. Must be from -315,576,000,000 to +315,576,
# 000,000 inclusive. Note: these bounds are computed from: 60 sec/min * 60 min/
# hr * 24 hr/day * 365.25 days/year * 10000 years
# Corresponds to the JSON property `seconds`
# @return [Fixnum]
attr_accessor :seconds
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@nanos = args[:nanos] if args.key?(:nanos)
@seconds = args[:seconds] if args.key?(:seconds)
end
end
# An Execution represents a collection of Steps. For instance, it could
# represent: - a mobile test executed across a range of device configurations -
# a jenkins job with a build step followed by a test step
# The maximum size of an execution message is 1 MiB.
# An Execution can be updated until its state is set to COMPLETE at which point
# it becomes immutable.
class Execution
include Google::Apis::Core::Hashable
# A Timestamp represents a point in time independent of any time zone or
# calendar, represented as seconds and fractions of seconds at nanosecond
# resolution in UTC Epoch time. It is encoded using the Proleptic Gregorian
# Calendar which extends the Gregorian calendar backwards to year one. It is
# encoded assuming all minutes are 60 seconds long, i.e. leap seconds are "
# smeared" so that no leap second table is needed for interpretation. Range is
# from 0001-01-01T00:00:00Z to 9999-12-31T23:59:59.999999999Z. By restricting to
# that range, we ensure that we can convert to and from RFC 3339 date strings.
# See [https://www.ietf.org/rfc/rfc3339.txt](https://www.ietf.org/rfc/rfc3339.
# txt).
# # Examples
# Example 1: Compute Timestamp from POSIX `time()`.
# Timestamp timestamp; timestamp.set_seconds(time(NULL)); timestamp.set_nanos(0);
# Example 2: Compute Timestamp from POSIX `gettimeofday()`.
# struct timeval tv; gettimeofday(&tv, NULL);
# Timestamp timestamp; timestamp.set_seconds(tv.tv_sec); timestamp.set_nanos(tv.
# tv_usec * 1000);
# Example 3: Compute Timestamp from Win32 `GetSystemTimeAsFileTime()`.
# FILETIME ft; GetSystemTimeAsFileTime(&ft); UINT64 ticks = (((UINT64)ft.
# dwHighDateTime) << 32) | ft.dwLowDateTime;
# // A Windows tick is 100 nanoseconds. Windows epoch 1601-01-01T00:00:00Z // is
# 11644473600 seconds before Unix epoch 1970-01-01T00:00:00Z. Timestamp
# timestamp; timestamp.set_seconds((INT64) ((ticks / 10000000) - 11644473600LL));
# timestamp.set_nanos((INT32) ((ticks % 10000000) * 100));
# Example 4: Compute Timestamp from Java `System.currentTimeMillis()`.
# long millis = System.currentTimeMillis();
# Timestamp timestamp = Timestamp.newBuilder().setSeconds(millis / 1000) .
# setNanos((int) ((millis % 1000) * 1000000)).build();
# Example 5: Compute Timestamp from current time in Python.
# timestamp = Timestamp() timestamp.GetCurrentTime()
# # JSON Mapping
# In JSON format, the Timestamp type is encoded as a string in the [RFC 3339](
# https://www.ietf.org/rfc/rfc3339.txt) format. That is, the format is "`year`-`
# month`-`day`T`hour`:`min`:`sec`[.`frac_sec`]Z" where `year` is always
# expressed using four digits while `month`, `day`, `hour`, `min`, and `sec` are
# zero-padded to two digits each. The fractional seconds, which can go up to 9
# digits (i.e. up to 1 nanosecond resolution), are optional. The "Z" suffix
# indicates the timezone ("UTC"); the timezone is required, though only UTC (as
# indicated by "Z") is currently supported.
# For example, "2017-01-15T01:30:15.01Z" encodes 15.01 seconds past 01:30 UTC on
# January 15, 2017.
# In JavaScript, one can convert a Date object to this format using the standard
# [toISOString()](https://developer.mozilla.org/en-US/docs/Web/JavaScript/
# Reference/Global_Objects/Date/toISOString] method. In Python, a standard `
# datetime.datetime` object can be converted to this format using [`strftime`](
# https://docs.python.org/2/library/time.html#time.strftime) with the time
# format spec '%Y-%m-%dT%H:%M:%S.%fZ'. Likewise, in Java, one can use the Joda
# Time's [`ISODateTimeFormat.dateTime()`]( http://www.joda.org/joda-time/apidocs/
# org/joda/time/format/ISODateTimeFormat.html#dateTime-- ) to obtain a formatter
# capable of generating timestamps in this format.
# Corresponds to the JSON property `completionTime`
# @return [Google::Apis::ToolresultsV1beta3::Timestamp]
attr_accessor :completion_time
# A Timestamp represents a point in time independent of any time zone or
# calendar, represented as seconds and fractions of seconds at nanosecond
# resolution in UTC Epoch time. It is encoded using the Proleptic Gregorian
# Calendar which extends the Gregorian calendar backwards to year one. It is
# encoded assuming all minutes are 60 seconds long, i.e. leap seconds are "
# smeared" so that no leap second table is needed for interpretation. Range is
# from 0001-01-01T00:00:00Z to 9999-12-31T23:59:59.999999999Z. By restricting to
# that range, we ensure that we can convert to and from RFC 3339 date strings.
# See [https://www.ietf.org/rfc/rfc3339.txt](https://www.ietf.org/rfc/rfc3339.
# txt).
# # Examples
# Example 1: Compute Timestamp from POSIX `time()`.
# Timestamp timestamp; timestamp.set_seconds(time(NULL)); timestamp.set_nanos(0);
# Example 2: Compute Timestamp from POSIX `gettimeofday()`.
# struct timeval tv; gettimeofday(&tv, NULL);
# Timestamp timestamp; timestamp.set_seconds(tv.tv_sec); timestamp.set_nanos(tv.
# tv_usec * 1000);
# Example 3: Compute Timestamp from Win32 `GetSystemTimeAsFileTime()`.
# FILETIME ft; GetSystemTimeAsFileTime(&ft); UINT64 ticks = (((UINT64)ft.
# dwHighDateTime) << 32) | ft.dwLowDateTime;
# // A Windows tick is 100 nanoseconds. Windows epoch 1601-01-01T00:00:00Z // is
# 11644473600 seconds before Unix epoch 1970-01-01T00:00:00Z. Timestamp
# timestamp; timestamp.set_seconds((INT64) ((ticks / 10000000) - 11644473600LL));
# timestamp.set_nanos((INT32) ((ticks % 10000000) * 100));
# Example 4: Compute Timestamp from Java `System.currentTimeMillis()`.
# long millis = System.currentTimeMillis();
# Timestamp timestamp = Timestamp.newBuilder().setSeconds(millis / 1000) .
# setNanos((int) ((millis % 1000) * 1000000)).build();
# Example 5: Compute Timestamp from current time in Python.
# timestamp = Timestamp() timestamp.GetCurrentTime()
# # JSON Mapping
# In JSON format, the Timestamp type is encoded as a string in the [RFC 3339](
# https://www.ietf.org/rfc/rfc3339.txt) format. That is, the format is "`year`-`
# month`-`day`T`hour`:`min`:`sec`[.`frac_sec`]Z" where `year` is always
# expressed using four digits while `month`, `day`, `hour`, `min`, and `sec` are
# zero-padded to two digits each. The fractional seconds, which can go up to 9
# digits (i.e. up to 1 nanosecond resolution), are optional. The "Z" suffix
# indicates the timezone ("UTC"); the timezone is required, though only UTC (as
# indicated by "Z") is currently supported.
# For example, "2017-01-15T01:30:15.01Z" encodes 15.01 seconds past 01:30 UTC on
# January 15, 2017.
# In JavaScript, one can convert a Date object to this format using the standard
# [toISOString()](https://developer.mozilla.org/en-US/docs/Web/JavaScript/
# Reference/Global_Objects/Date/toISOString] method. In Python, a standard `
# datetime.datetime` object can be converted to this format using [`strftime`](
# https://docs.python.org/2/library/time.html#time.strftime) with the time
# format spec '%Y-%m-%dT%H:%M:%S.%fZ'. Likewise, in Java, one can use the Joda
# Time's [`ISODateTimeFormat.dateTime()`]( http://www.joda.org/joda-time/apidocs/
# org/joda/time/format/ISODateTimeFormat.html#dateTime-- ) to obtain a formatter
# capable of generating timestamps in this format.
# Corresponds to the JSON property `creationTime`
# @return [Google::Apis::ToolresultsV1beta3::Timestamp]
attr_accessor :creation_time
# A unique identifier within a History for this Execution.
# Returns INVALID_ARGUMENT if this field is set or overwritten by the caller.
# - In response always set - In create/update request: never set
# Corresponds to the JSON property `executionId`
# @return [String]
attr_accessor :execution_id
# Interprets a result so that humans and machines can act on it.
# Corresponds to the JSON property `outcome`
# @return [Google::Apis::ToolresultsV1beta3::Outcome]
attr_accessor :outcome
# The details about how to run the execution.
# Corresponds to the JSON property `specification`
# @return [Google::Apis::ToolresultsV1beta3::Specification]
attr_accessor :specification
# The initial state is IN_PROGRESS.
# The only legal state transitions is from IN_PROGRESS to COMPLETE.
# A PRECONDITION_FAILED will be returned if an invalid transition is requested.
# The state can only be set to COMPLETE once. A FAILED_PRECONDITION will be
# returned if the state is set to COMPLETE multiple times.
# If the state is set to COMPLETE, all the in-progress steps within the
# execution will be set as COMPLETE. If the outcome of the step is not set, the
# outcome will be set to INCONCLUSIVE.
# - In response always set - In create/update request: optional
# Corresponds to the JSON property `state`
# @return [String]
attr_accessor :state
# TestExecution Matrix ID that the TestExecutionService uses.
# - In response: present if set by create - In create: optional - In update:
# never set
# Corresponds to the JSON property `testExecutionMatrixId`
# @return [String]
attr_accessor :test_execution_matrix_id
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@completion_time = args[:completion_time] if args.key?(:completion_time)
@creation_time = args[:creation_time] if args.key?(:creation_time)
@execution_id = args[:execution_id] if args.key?(:execution_id)
@outcome = args[:outcome] if args.key?(:outcome)
@specification = args[:specification] if args.key?(:specification)
@state = args[:state] if args.key?(:state)
@test_execution_matrix_id = args[:test_execution_matrix_id] if args.key?(:test_execution_matrix_id)
end
end
#
class FailureDetail
include Google::Apis::Core::Hashable
# If the failure was severe because the system (app) under test crashed.
# Corresponds to the JSON property `crashed`
# @return [Boolean]
attr_accessor :crashed
alias_method :crashed?, :crashed
# If an app is not installed and thus no test can be run with the app. This
# might be caused by trying to run a test on an unsupported platform.
# Corresponds to the JSON property `notInstalled`
# @return [Boolean]
attr_accessor :not_installed
alias_method :not_installed?, :not_installed
# If a native process (including any other than the app) crashed.
# Corresponds to the JSON property `otherNativeCrash`
# @return [Boolean]
attr_accessor :other_native_crash
alias_method :other_native_crash?, :other_native_crash
# If the test overran some time limit, and that is why it failed.
# Corresponds to the JSON property `timedOut`
# @return [Boolean]
attr_accessor :timed_out
alias_method :timed_out?, :timed_out
# If the robo was unable to crawl the app; perhaps because the app did not start.
# Corresponds to the JSON property `unableToCrawl`
# @return [Boolean]
attr_accessor :unable_to_crawl
alias_method :unable_to_crawl?, :unable_to_crawl
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@crashed = args[:crashed] if args.key?(:crashed)
@not_installed = args[:not_installed] if args.key?(:not_installed)
@other_native_crash = args[:other_native_crash] if args.key?(:other_native_crash)
@timed_out = args[:timed_out] if args.key?(:timed_out)
@unable_to_crawl = args[:unable_to_crawl] if args.key?(:unable_to_crawl)
end
end
# A reference to a file.
class FileReference
include Google::Apis::Core::Hashable
# The URI of a file stored in Google Cloud Storage.
# For example: http://storage.googleapis.com/mybucket/path/to/test.xml or in
# gsutil format: gs://mybucket/path/to/test.xml with version-specific info, gs://
# mybucket/path/to/test.xml#1360383693690000
# An INVALID_ARGUMENT error will be returned if the URI format is not supported.
# - In response: always set - In create/update request: always set
# Corresponds to the JSON property `fileUri`
# @return [String]
attr_accessor :file_uri
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@file_uri = args[:file_uri] if args.key?(:file_uri)
end
end
# Graphics statistics for the App. The information is collected from 'adb shell
# dumpsys graphicsstats'. For more info see: https://developer.android.com/
# training/testing/performance.html Statistics will only be present for API 23+.
class GraphicsStats
include Google::Apis::Core::Hashable
# Histogram of frame render times. There should be 154 buckets ranging from [5ms,
# 6ms) to [4950ms, infinity)
# Corresponds to the JSON property `buckets`
# @return [Array<Google::Apis::ToolresultsV1beta3::GraphicsStatsBucket>]
attr_accessor :buckets
# Total "high input latency" events.
# Corresponds to the JSON property `highInputLatencyCount`
# @return [Fixnum]
attr_accessor :high_input_latency_count
# Total frames with slow render time. Should be <= total_frames.
# Corresponds to the JSON property `jankyFrames`
# @return [Fixnum]
attr_accessor :janky_frames
# Total "missed vsync" events.
# Corresponds to the JSON property `missedVsyncCount`
# @return [Fixnum]
attr_accessor :missed_vsync_count
# 50th percentile frame render time in milliseconds.
# Corresponds to the JSON property `p50Millis`
# @return [Fixnum]
attr_accessor :p50_millis
# 90th percentile frame render time in milliseconds.
# Corresponds to the JSON property `p90Millis`
# @return [Fixnum]
attr_accessor :p90_millis
# 95th percentile frame render time in milliseconds.
# Corresponds to the JSON property `p95Millis`
# @return [Fixnum]
attr_accessor :p95_millis
# 99th percentile frame render time in milliseconds.
# Corresponds to the JSON property `p99Millis`
# @return [Fixnum]
attr_accessor :p99_millis
# Total "slow bitmap upload" events.
# Corresponds to the JSON property `slowBitmapUploadCount`
# @return [Fixnum]
attr_accessor :slow_bitmap_upload_count
# Total "slow draw" events.
# Corresponds to the JSON property `slowDrawCount`
# @return [Fixnum]
attr_accessor :slow_draw_count
# Total "slow UI thread" events.
# Corresponds to the JSON property `slowUiThreadCount`
# @return [Fixnum]
attr_accessor :slow_ui_thread_count
# Total frames rendered by package.
# Corresponds to the JSON property `totalFrames`
# @return [Fixnum]
attr_accessor :total_frames
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@buckets = args[:buckets] if args.key?(:buckets)
@high_input_latency_count = args[:high_input_latency_count] if args.key?(:high_input_latency_count)
@janky_frames = args[:janky_frames] if args.key?(:janky_frames)
@missed_vsync_count = args[:missed_vsync_count] if args.key?(:missed_vsync_count)
@p50_millis = args[:p50_millis] if args.key?(:p50_millis)
@p90_millis = args[:p90_millis] if args.key?(:p90_millis)
@p95_millis = args[:p95_millis] if args.key?(:p95_millis)
@p99_millis = args[:p99_millis] if args.key?(:p99_millis)
@slow_bitmap_upload_count = args[:slow_bitmap_upload_count] if args.key?(:slow_bitmap_upload_count)
@slow_draw_count = args[:slow_draw_count] if args.key?(:slow_draw_count)
@slow_ui_thread_count = args[:slow_ui_thread_count] if args.key?(:slow_ui_thread_count)
@total_frames = args[:total_frames] if args.key?(:total_frames)
end
end
#
class GraphicsStatsBucket
include Google::Apis::Core::Hashable
# Number of frames in the bucket.
# Corresponds to the JSON property `frameCount`
# @return [Fixnum]
attr_accessor :frame_count
# Lower bound of render time in milliseconds.
# Corresponds to the JSON property `renderMillis`
# @return [Fixnum]
attr_accessor :render_millis
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@frame_count = args[:frame_count] if args.key?(:frame_count)
@render_millis = args[:render_millis] if args.key?(:render_millis)
end
end
# A History represents a sorted list of Executions ordered by the
# start_timestamp_millis field (descending). It can be used to group all the
# Executions of a continuous build.
# Note that the ordering only operates on one-dimension. If a repository has
# multiple branches, it means that multiple histories will need to be used in
# order to order Executions per branch.
class History
include Google::Apis::Core::Hashable
# A short human-readable (plain text) name to display in the UI. Maximum of 100
# characters.
# - In response: present if set during create. - In create request: optional
# Corresponds to the JSON property `displayName`
# @return [String]
attr_accessor :display_name
# A unique identifier within a project for this History.
# Returns INVALID_ARGUMENT if this field is set or overwritten by the caller.
# - In response always set - In create request: never set
# Corresponds to the JSON property `historyId`
# @return [String]
attr_accessor :history_id
# A name to uniquely identify a history within a project. Maximum of 100
# characters.
# - In response always set - In create request: always set
# Corresponds to the JSON property `name`
# @return [String]
attr_accessor :name
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@display_name = args[:display_name] if args.key?(:display_name)
@history_id = args[:history_id] if args.key?(:history_id)
@name = args[:name] if args.key?(:name)
end
end
# An image, with a link to the main image and a thumbnail.
class Image
include Google::Apis::Core::Hashable
# The `Status` type defines a logical error model that is suitable for different
# programming environments, including REST APIs and RPC APIs. It is used by [
# gRPC](https://github.com/grpc). The error model is designed to be:
# - Simple to use and understand for most users - Flexible enough to meet
# unexpected needs
# # Overview
# The `Status` message contains three pieces of data: error code, error message,
# and error details. The error code should be an enum value of [google.rpc.Code][
# ], but it may accept additional error codes if needed. The error message
# should be a developer-facing English message that helps developers *understand*
# and *resolve* the error. If a localized user-facing error message is needed,
# put the localized message in the error details or localize it in the client.
# The optional error details may contain arbitrary information about the error.
# There is a predefined set of error detail types in the package `google.rpc`
# that can be used for common error conditions.
# # Language mapping
# The `Status` message is the logical representation of the error model, but it
# is not necessarily the actual wire format. When the `Status` message is
# exposed in different client libraries and different wire protocols, it can be
# mapped differently. For example, it will likely be mapped to some exceptions
# in Java, but more likely mapped to some error codes in C.
# # Other uses
# The error model and the `Status` message can be used in a variety of
# environments, either with or without APIs, to provide a consistent developer
# experience across different environments.
# Example uses of this error model include:
# - Partial errors. If a service needs to return partial errors to the client,
# it may embed the `Status` in the normal response to indicate the partial
# errors.
# - Workflow errors. A typical workflow has multiple steps. Each step may have a
# `Status` message for error reporting.
# - Batch operations. If a client uses batch request and batch response, the `
# Status` message should be used directly inside batch response, one for each
# error sub-response.
# - Asynchronous operations. If an API call embeds asynchronous operation
# results in its response, the status of those operations should be represented
# directly using the `Status` message.
# - Logging. If some API errors are stored in logs, the message `Status` could
# be used directly after any stripping needed for security/privacy reasons.
# Corresponds to the JSON property `error`
# @return [Google::Apis::ToolresultsV1beta3::Status]
attr_accessor :error
# A reference to a ToolExecution output file.
# Corresponds to the JSON property `sourceImage`
# @return [Google::Apis::ToolresultsV1beta3::ToolOutputReference]
attr_accessor :source_image
# The step to which the image is attached.
# Always set.
# Corresponds to the JSON property `stepId`
# @return [String]
attr_accessor :step_id
# A single thumbnail, with its size and format.
# Corresponds to the JSON property `thumbnail`
# @return [Google::Apis::ToolresultsV1beta3::Thumbnail]
attr_accessor :thumbnail
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@error = args[:error] if args.key?(:error)
@source_image = args[:source_image] if args.key?(:source_image)
@step_id = args[:step_id] if args.key?(:step_id)
@thumbnail = args[:thumbnail] if args.key?(:thumbnail)
end
end
#
class InconclusiveDetail
include Google::Apis::Core::Hashable
# If the end user aborted the test execution before a pass or fail could be
# determined. For example, the user pressed ctrl-c which sent a kill signal to
# the test runner while the test was running.
# Corresponds to the JSON property `abortedByUser`
# @return [Boolean]
attr_accessor :aborted_by_user
alias_method :aborted_by_user?, :aborted_by_user
# If the test runner could not determine success or failure because the test
# depends on a component other than the system under test which failed.
# For example, a mobile test requires provisioning a device where the test
# executes, and that provisioning can fail.
# Corresponds to the JSON property `infrastructureFailure`
# @return [Boolean]
attr_accessor :infrastructure_failure
alias_method :infrastructure_failure?, :infrastructure_failure
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@aborted_by_user = args[:aborted_by_user] if args.key?(:aborted_by_user)
@infrastructure_failure = args[:infrastructure_failure] if args.key?(:infrastructure_failure)
end
end
#
class ListExecutionsResponse
include Google::Apis::Core::Hashable
# Executions.
# Always set.
# Corresponds to the JSON property `executions`
# @return [Array<Google::Apis::ToolresultsV1beta3::Execution>]
attr_accessor :executions
# A continuation token to resume the query at the next item.
# Will only be set if there are more Executions to fetch.
# Corresponds to the JSON property `nextPageToken`
# @return [String]
attr_accessor :next_page_token
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@executions = args[:executions] if args.key?(:executions)
@next_page_token = args[:next_page_token] if args.key?(:next_page_token)
end
end
# Response message for HistoryService.List
class ListHistoriesResponse
include Google::Apis::Core::Hashable
# Histories.
# Corresponds to the JSON property `histories`
# @return [Array<Google::Apis::ToolresultsV1beta3::History>]
attr_accessor :histories
# A continuation token to resume the query at the next item.
# Will only be set if there are more histories to fetch.
# Tokens are valid for up to one hour from the time of the first list request.
# For instance, if you make a list request at 1PM and use the token from this
# first request 10 minutes later, the token from this second response will only
# be valid for 50 minutes.
# Corresponds to the JSON property `nextPageToken`
# @return [String]
attr_accessor :next_page_token
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@histories = args[:histories] if args.key?(:histories)
@next_page_token = args[:next_page_token] if args.key?(:next_page_token)
end
end
#
class ListPerfSampleSeriesResponse
include Google::Apis::Core::Hashable
# The resulting PerfSampleSeries sorted by id
# Corresponds to the JSON property `perfSampleSeries`
# @return [Array<Google::Apis::ToolresultsV1beta3::PerfSampleSeries>]
attr_accessor :perf_sample_series
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@perf_sample_series = args[:perf_sample_series] if args.key?(:perf_sample_series)
end
end
#
class ListPerfSamplesResponse
include Google::Apis::Core::Hashable
# Optional, returned if result size exceeds the page size specified in the
# request (or the default page size, 500, if unspecified). It indicates the last
# sample timestamp to be used as page_token in subsequent request
# Corresponds to the JSON property `nextPageToken`
# @return [String]
attr_accessor :next_page_token
#
# Corresponds to the JSON property `perfSamples`
# @return [Array<Google::Apis::ToolresultsV1beta3::PerfSample>]
attr_accessor :perf_samples
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@next_page_token = args[:next_page_token] if args.key?(:next_page_token)
@perf_samples = args[:perf_samples] if args.key?(:perf_samples)
end
end
#
class ListScreenshotClustersResponse
include Google::Apis::Core::Hashable
# The set of clusters associated with an execution Always set
# Corresponds to the JSON property `clusters`
# @return [Array<Google::Apis::ToolresultsV1beta3::ScreenshotCluster>]
attr_accessor :clusters
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@clusters = args[:clusters] if args.key?(:clusters)
end
end
# A response containing the thumbnails in a step.
class ListStepThumbnailsResponse
include Google::Apis::Core::Hashable
# A continuation token to resume the query at the next item.
# If set, indicates that there are more thumbnails to read, by calling list
# again with this value in the page_token field.
# Corresponds to the JSON property `nextPageToken`
# @return [String]
attr_accessor :next_page_token
# A list of image data.
# Images are returned in a deterministic order; they are ordered by these
# factors, in order of importance: * First, by their associated test case.
# Images without a test case are considered greater than images with one. *
# Second, by their creation time. Images without a creation time are greater
# than images with one. * Third, by the order in which they were added to the
# step (by calls to CreateStep or UpdateStep).
# Corresponds to the JSON property `thumbnails`
# @return [Array<Google::Apis::ToolresultsV1beta3::Image>]
attr_accessor :thumbnails
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@next_page_token = args[:next_page_token] if args.key?(:next_page_token)
@thumbnails = args[:thumbnails] if args.key?(:thumbnails)
end
end
# Response message for StepService.List.
class ListStepsResponse
include Google::Apis::Core::Hashable
# A continuation token to resume the query at the next item.
# If set, indicates that there are more steps to read, by calling list again
# with this value in the page_token field.
# Corresponds to the JSON property `nextPageToken`
# @return [String]
attr_accessor :next_page_token
# Steps.
# Corresponds to the JSON property `steps`
# @return [Array<Google::Apis::ToolresultsV1beta3::Step>]
attr_accessor :steps
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@next_page_token = args[:next_page_token] if args.key?(:next_page_token)
@steps = args[:steps] if args.key?(:steps)
end
end
#
class MemoryInfo
include Google::Apis::Core::Hashable
# Maximum memory that can be allocated to the process in KiB
# Corresponds to the JSON property `memoryCapInKibibyte`
# @return [Fixnum]
attr_accessor :memory_cap_in_kibibyte
# Total memory available on the device in KiB
# Corresponds to the JSON property `memoryTotalInKibibyte`
# @return [Fixnum]
attr_accessor :memory_total_in_kibibyte
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@memory_cap_in_kibibyte = args[:memory_cap_in_kibibyte] if args.key?(:memory_cap_in_kibibyte)
@memory_total_in_kibibyte = args[:memory_total_in_kibibyte] if args.key?(:memory_total_in_kibibyte)
end
end
# Interprets a result so that humans and machines can act on it.
class Outcome
include Google::Apis::Core::Hashable
# More information about a FAILURE outcome.
# Returns INVALID_ARGUMENT if this field is set but the summary is not FAILURE.
# Optional
# Corresponds to the JSON property `failureDetail`
# @return [Google::Apis::ToolresultsV1beta3::FailureDetail]
attr_accessor :failure_detail
# More information about an INCONCLUSIVE outcome.
# Returns INVALID_ARGUMENT if this field is set but the summary is not
# INCONCLUSIVE.
# Optional
# Corresponds to the JSON property `inconclusiveDetail`
# @return [Google::Apis::ToolresultsV1beta3::InconclusiveDetail]
attr_accessor :inconclusive_detail
# More information about a SKIPPED outcome.
# Returns INVALID_ARGUMENT if this field is set but the summary is not SKIPPED.
# Optional
# Corresponds to the JSON property `skippedDetail`
# @return [Google::Apis::ToolresultsV1beta3::SkippedDetail]
attr_accessor :skipped_detail
# More information about a SUCCESS outcome.
# Returns INVALID_ARGUMENT if this field is set but the summary is not SUCCESS.
# Optional
# Corresponds to the JSON property `successDetail`
# @return [Google::Apis::ToolresultsV1beta3::SuccessDetail]
attr_accessor :success_detail
# The simplest way to interpret a result.
# Required
# Corresponds to the JSON property `summary`
# @return [String]
attr_accessor :summary
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@failure_detail = args[:failure_detail] if args.key?(:failure_detail)
@inconclusive_detail = args[:inconclusive_detail] if args.key?(:inconclusive_detail)
@skipped_detail = args[:skipped_detail] if args.key?(:skipped_detail)
@success_detail = args[:success_detail] if args.key?(:success_detail)
@summary = args[:summary] if args.key?(:summary)
end
end
# Encapsulates performance environment info
class PerfEnvironment
include Google::Apis::Core::Hashable
# CPU related environment info
# Corresponds to the JSON property `cpuInfo`
# @return [Google::Apis::ToolresultsV1beta3::CpuInfo]
attr_accessor :cpu_info
# Memory related environment info
# Corresponds to the JSON property `memoryInfo`
# @return [Google::Apis::ToolresultsV1beta3::MemoryInfo]
attr_accessor :memory_info
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@cpu_info = args[:cpu_info] if args.key?(:cpu_info)
@memory_info = args[:memory_info] if args.key?(:memory_info)
end
end
# A summary of perf metrics collected and performance environment info
class PerfMetricsSummary
include Google::Apis::Core::Hashable
#
# Corresponds to the JSON property `appStartTime`
# @return [Google::Apis::ToolresultsV1beta3::AppStartTime]
attr_accessor :app_start_time
# A tool results execution ID.
# Corresponds to the JSON property `executionId`
# @return [String]
attr_accessor :execution_id
# Graphics statistics for the App. The information is collected from 'adb shell
# dumpsys graphicsstats'. For more info see: https://developer.android.com/
# training/testing/performance.html Statistics will only be present for API 23+.
# Corresponds to the JSON property `graphicsStats`
# @return [Google::Apis::ToolresultsV1beta3::GraphicsStats]
attr_accessor :graphics_stats
# A tool results history ID.
# Corresponds to the JSON property `historyId`
# @return [String]
attr_accessor :history_id
# Encapsulates performance environment info
# Corresponds to the JSON property `perfEnvironment`
# @return [Google::Apis::ToolresultsV1beta3::PerfEnvironment]
attr_accessor :perf_environment
# Set of resource collected
# Corresponds to the JSON property `perfMetrics`
# @return [Array<String>]
attr_accessor :perf_metrics
# The cloud project
# Corresponds to the JSON property `projectId`
# @return [String]
attr_accessor :project_id
# A tool results step ID.
# Corresponds to the JSON property `stepId`
# @return [String]
attr_accessor :step_id
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@app_start_time = args[:app_start_time] if args.key?(:app_start_time)
@execution_id = args[:execution_id] if args.key?(:execution_id)
@graphics_stats = args[:graphics_stats] if args.key?(:graphics_stats)
@history_id = args[:history_id] if args.key?(:history_id)
@perf_environment = args[:perf_environment] if args.key?(:perf_environment)
@perf_metrics = args[:perf_metrics] if args.key?(:perf_metrics)
@project_id = args[:project_id] if args.key?(:project_id)
@step_id = args[:step_id] if args.key?(:step_id)
end
end
# Resource representing a single performance measure or data point
class PerfSample
include Google::Apis::Core::Hashable
# A Timestamp represents a point in time independent of any time zone or
# calendar, represented as seconds and fractions of seconds at nanosecond
# resolution in UTC Epoch time. It is encoded using the Proleptic Gregorian
# Calendar which extends the Gregorian calendar backwards to year one. It is
# encoded assuming all minutes are 60 seconds long, i.e. leap seconds are "
# smeared" so that no leap second table is needed for interpretation. Range is
# from 0001-01-01T00:00:00Z to 9999-12-31T23:59:59.999999999Z. By restricting to
# that range, we ensure that we can convert to and from RFC 3339 date strings.
# See [https://www.ietf.org/rfc/rfc3339.txt](https://www.ietf.org/rfc/rfc3339.
# txt).
# # Examples
# Example 1: Compute Timestamp from POSIX `time()`.
# Timestamp timestamp; timestamp.set_seconds(time(NULL)); timestamp.set_nanos(0);
# Example 2: Compute Timestamp from POSIX `gettimeofday()`.
# struct timeval tv; gettimeofday(&tv, NULL);
# Timestamp timestamp; timestamp.set_seconds(tv.tv_sec); timestamp.set_nanos(tv.
# tv_usec * 1000);
# Example 3: Compute Timestamp from Win32 `GetSystemTimeAsFileTime()`.
# FILETIME ft; GetSystemTimeAsFileTime(&ft); UINT64 ticks = (((UINT64)ft.
# dwHighDateTime) << 32) | ft.dwLowDateTime;
# // A Windows tick is 100 nanoseconds. Windows epoch 1601-01-01T00:00:00Z // is
# 11644473600 seconds before Unix epoch 1970-01-01T00:00:00Z. Timestamp
# timestamp; timestamp.set_seconds((INT64) ((ticks / 10000000) - 11644473600LL));
# timestamp.set_nanos((INT32) ((ticks % 10000000) * 100));
# Example 4: Compute Timestamp from Java `System.currentTimeMillis()`.
# long millis = System.currentTimeMillis();
# Timestamp timestamp = Timestamp.newBuilder().setSeconds(millis / 1000) .
# setNanos((int) ((millis % 1000) * 1000000)).build();
# Example 5: Compute Timestamp from current time in Python.
# timestamp = Timestamp() timestamp.GetCurrentTime()
# # JSON Mapping
# In JSON format, the Timestamp type is encoded as a string in the [RFC 3339](
# https://www.ietf.org/rfc/rfc3339.txt) format. That is, the format is "`year`-`
# month`-`day`T`hour`:`min`:`sec`[.`frac_sec`]Z" where `year` is always
# expressed using four digits while `month`, `day`, `hour`, `min`, and `sec` are
# zero-padded to two digits each. The fractional seconds, which can go up to 9
# digits (i.e. up to 1 nanosecond resolution), are optional. The "Z" suffix
# indicates the timezone ("UTC"); the timezone is required, though only UTC (as
# indicated by "Z") is currently supported.
# For example, "2017-01-15T01:30:15.01Z" encodes 15.01 seconds past 01:30 UTC on
# January 15, 2017.
# In JavaScript, one can convert a Date object to this format using the standard
# [toISOString()](https://developer.mozilla.org/en-US/docs/Web/JavaScript/
# Reference/Global_Objects/Date/toISOString] method. In Python, a standard `
# datetime.datetime` object can be converted to this format using [`strftime`](
# https://docs.python.org/2/library/time.html#time.strftime) with the time
# format spec '%Y-%m-%dT%H:%M:%S.%fZ'. Likewise, in Java, one can use the Joda
# Time's [`ISODateTimeFormat.dateTime()`]( http://www.joda.org/joda-time/apidocs/
# org/joda/time/format/ISODateTimeFormat.html#dateTime-- ) to obtain a formatter
# capable of generating timestamps in this format.
# Corresponds to the JSON property `sampleTime`
# @return [Google::Apis::ToolresultsV1beta3::Timestamp]
attr_accessor :sample_time
# Value observed
# Corresponds to the JSON property `value`
# @return [Float]
attr_accessor :value
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@sample_time = args[:sample_time] if args.key?(:sample_time)
@value = args[:value] if args.key?(:value)
end
end
# Resource representing a collection of performance samples (or data points)
class PerfSampleSeries
include Google::Apis::Core::Hashable
# Encapsulates the metadata for basic sample series represented by a line chart
# Corresponds to the JSON property `basicPerfSampleSeries`
# @return [Google::Apis::ToolresultsV1beta3::BasicPerfSampleSeries]
attr_accessor :basic_perf_sample_series
# A tool results execution ID.
# Corresponds to the JSON property `executionId`
# @return [String]
attr_accessor :execution_id
# A tool results history ID.
# Corresponds to the JSON property `historyId`
# @return [String]
attr_accessor :history_id
# The cloud project
# Corresponds to the JSON property `projectId`
# @return [String]
attr_accessor :project_id
# A sample series id
# Corresponds to the JSON property `sampleSeriesId`
# @return [String]
attr_accessor :sample_series_id
# A tool results step ID.
# Corresponds to the JSON property `stepId`
# @return [String]
attr_accessor :step_id
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@basic_perf_sample_series = args[:basic_perf_sample_series] if args.key?(:basic_perf_sample_series)
@execution_id = args[:execution_id] if args.key?(:execution_id)
@history_id = args[:history_id] if args.key?(:history_id)
@project_id = args[:project_id] if args.key?(:project_id)
@sample_series_id = args[:sample_series_id] if args.key?(:sample_series_id)
@step_id = args[:step_id] if args.key?(:step_id)
end
end
# Per-project settings for the Tool Results service.
class ProjectSettings
include Google::Apis::Core::Hashable
# The name of the Google Cloud Storage bucket to which results are written.
# By default, this is unset.
# In update request: optional In response: optional
# Corresponds to the JSON property `defaultBucket`
# @return [String]
attr_accessor :default_bucket
# The name of the project's settings.
# Always of the form: projects/`project-id`/settings
# In update request: never set In response: always set
# Corresponds to the JSON property `name`
# @return [String]
attr_accessor :name
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@default_bucket = args[:default_bucket] if args.key?(:default_bucket)
@name = args[:name] if args.key?(:name)
end
end
# Request message for StepService.PublishXunitXmlFiles.
class PublishXunitXmlFilesRequest
include Google::Apis::Core::Hashable
# URI of the Xunit XML files to publish.
# The maximum size of the file this reference is pointing to is 50MB.
# Required.
# Corresponds to the JSON property `xunitXmlFiles`
# @return [Array<Google::Apis::ToolresultsV1beta3::FileReference>]
attr_accessor :xunit_xml_files
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@xunit_xml_files = args[:xunit_xml_files] if args.key?(:xunit_xml_files)
end
end
#
class Screen
include Google::Apis::Core::Hashable
# File reference of the png file. Required.
# Corresponds to the JSON property `fileReference`
# @return [String]
attr_accessor :file_reference
# Locale of the device that the screenshot was taken on. Required.
# Corresponds to the JSON property `locale`
# @return [String]
attr_accessor :locale
# Model of the device that the screenshot was taken on. Required.
# Corresponds to the JSON property `model`
# @return [String]
attr_accessor :model
# OS version of the device that the screenshot was taken on. Required.
# Corresponds to the JSON property `version`
# @return [String]
attr_accessor :version
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@file_reference = args[:file_reference] if args.key?(:file_reference)
@locale = args[:locale] if args.key?(:locale)
@model = args[:model] if args.key?(:model)
@version = args[:version] if args.key?(:version)
end
end
#
class ScreenshotCluster
include Google::Apis::Core::Hashable
# A string that describes the activity of every screen in the cluster.
# Corresponds to the JSON property `activity`
# @return [String]
attr_accessor :activity
# A unique identifier for the cluster.
# Corresponds to the JSON property `clusterId`
# @return [String]
attr_accessor :cluster_id
# A singular screen that represents the cluster as a whole. This screen will act
# as the "cover" of the entire cluster. When users look at the clusters, only
# the key screen from each cluster will be shown. Which screen is the key screen
# is determined by the ClusteringAlgorithm
# Corresponds to the JSON property `keyScreen`
# @return [Google::Apis::ToolresultsV1beta3::Screen]
attr_accessor :key_screen
# Full list of screens.
# Corresponds to the JSON property `screens`
# @return [Array<Google::Apis::ToolresultsV1beta3::Screen>]
attr_accessor :screens
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@activity = args[:activity] if args.key?(:activity)
@cluster_id = args[:cluster_id] if args.key?(:cluster_id)
@key_screen = args[:key_screen] if args.key?(:key_screen)
@screens = args[:screens] if args.key?(:screens)
end
end
#
class SkippedDetail
include Google::Apis::Core::Hashable
# If the App doesn't support the specific API level.
# Corresponds to the JSON property `incompatibleAppVersion`
# @return [Boolean]
attr_accessor :incompatible_app_version
alias_method :incompatible_app_version?, :incompatible_app_version
# If the App doesn't run on the specific architecture, for example, x86.
# Corresponds to the JSON property `incompatibleArchitecture`
# @return [Boolean]
attr_accessor :incompatible_architecture
alias_method :incompatible_architecture?, :incompatible_architecture
# If the requested OS version doesn't run on the specific device model.
# Corresponds to the JSON property `incompatibleDevice`
# @return [Boolean]
attr_accessor :incompatible_device
alias_method :incompatible_device?, :incompatible_device
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@incompatible_app_version = args[:incompatible_app_version] if args.key?(:incompatible_app_version)
@incompatible_architecture = args[:incompatible_architecture] if args.key?(:incompatible_architecture)
@incompatible_device = args[:incompatible_device] if args.key?(:incompatible_device)
end
end
# The details about how to run the execution.
class Specification
include Google::Apis::Core::Hashable
# An Android mobile test specification.
# Corresponds to the JSON property `androidTest`
# @return [Google::Apis::ToolresultsV1beta3::AndroidTest]
attr_accessor :android_test
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@android_test = args[:android_test] if args.key?(:android_test)
end
end
# A stacktrace.
class StackTrace
include Google::Apis::Core::Hashable
# Exception cluster ID
# Corresponds to the JSON property `clusterId`
# @return [String]
attr_accessor :cluster_id
# The stack trace message.
# Required
# Corresponds to the JSON property `exception`
# @return [String]
attr_accessor :exception
# Exception report ID
# Corresponds to the JSON property `reportId`
# @return [String]
attr_accessor :report_id
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@cluster_id = args[:cluster_id] if args.key?(:cluster_id)
@exception = args[:exception] if args.key?(:exception)
@report_id = args[:report_id] if args.key?(:report_id)
end
end
# The `Status` type defines a logical error model that is suitable for different
# programming environments, including REST APIs and RPC APIs. It is used by [
# gRPC](https://github.com/grpc). The error model is designed to be:
# - Simple to use and understand for most users - Flexible enough to meet
# unexpected needs
# # Overview
# The `Status` message contains three pieces of data: error code, error message,
# and error details. The error code should be an enum value of [google.rpc.Code][
# ], but it may accept additional error codes if needed. The error message
# should be a developer-facing English message that helps developers *understand*
# and *resolve* the error. If a localized user-facing error message is needed,
# put the localized message in the error details or localize it in the client.
# The optional error details may contain arbitrary information about the error.
# There is a predefined set of error detail types in the package `google.rpc`
# that can be used for common error conditions.
# # Language mapping
# The `Status` message is the logical representation of the error model, but it
# is not necessarily the actual wire format. When the `Status` message is
# exposed in different client libraries and different wire protocols, it can be
# mapped differently. For example, it will likely be mapped to some exceptions
# in Java, but more likely mapped to some error codes in C.
# # Other uses
# The error model and the `Status` message can be used in a variety of
# environments, either with or without APIs, to provide a consistent developer
# experience across different environments.
# Example uses of this error model include:
# - Partial errors. If a service needs to return partial errors to the client,
# it may embed the `Status` in the normal response to indicate the partial
# errors.
# - Workflow errors. A typical workflow has multiple steps. Each step may have a
# `Status` message for error reporting.
# - Batch operations. If a client uses batch request and batch response, the `
# Status` message should be used directly inside batch response, one for each
# error sub-response.
# - Asynchronous operations. If an API call embeds asynchronous operation
# results in its response, the status of those operations should be represented
# directly using the `Status` message.
# - Logging. If some API errors are stored in logs, the message `Status` could
# be used directly after any stripping needed for security/privacy reasons.
class Status
include Google::Apis::Core::Hashable
# The status code, which should be an enum value of [google.rpc.Code][].
# Corresponds to the JSON property `code`
# @return [Fixnum]
attr_accessor :code
# A list of messages that carry the error details. There is a common set of
# message types for APIs to use.
# Corresponds to the JSON property `details`
# @return [Array<Google::Apis::ToolresultsV1beta3::Any>]
attr_accessor :details
# A developer-facing error message, which should be in English. Any user-facing
# error message should be localized and sent in the [google.rpc.Status.details][]
# field, or localized by the client.
# Corresponds to the JSON property `message`
# @return [String]
attr_accessor :message
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@code = args[:code] if args.key?(:code)
@details = args[:details] if args.key?(:details)
@message = args[:message] if args.key?(:message)
end
end
# A Step represents a single operation performed as part of Execution. A step
# can be used to represent the execution of a tool ( for example a test runner
# execution or an execution of a compiler).
# Steps can overlap (for instance two steps might have the same start time if
# some operations are done in parallel).
# Here is an example, let's consider that we have a continuous build is
# executing a test runner for each iteration. The workflow would look like: -
# user creates a Execution with id 1 - user creates an TestExecutionStep with id
# 100 for Execution 1 - user update TestExecutionStep with id 100 to add a raw
# xml log + the service parses the xml logs and returns a TestExecutionStep with
# updated TestResult(s). - user update the status of TestExecutionStep with id
# 100 to COMPLETE
# A Step can be updated until its state is set to COMPLETE at which points it
# becomes immutable.
class Step
include Google::Apis::Core::Hashable
# A Timestamp represents a point in time independent of any time zone or
# calendar, represented as seconds and fractions of seconds at nanosecond
# resolution in UTC Epoch time. It is encoded using the Proleptic Gregorian
# Calendar which extends the Gregorian calendar backwards to year one. It is
# encoded assuming all minutes are 60 seconds long, i.e. leap seconds are "
# smeared" so that no leap second table is needed for interpretation. Range is
# from 0001-01-01T00:00:00Z to 9999-12-31T23:59:59.999999999Z. By restricting to
# that range, we ensure that we can convert to and from RFC 3339 date strings.
# See [https://www.ietf.org/rfc/rfc3339.txt](https://www.ietf.org/rfc/rfc3339.
# txt).
# # Examples
# Example 1: Compute Timestamp from POSIX `time()`.
# Timestamp timestamp; timestamp.set_seconds(time(NULL)); timestamp.set_nanos(0);
# Example 2: Compute Timestamp from POSIX `gettimeofday()`.
# struct timeval tv; gettimeofday(&tv, NULL);
# Timestamp timestamp; timestamp.set_seconds(tv.tv_sec); timestamp.set_nanos(tv.
# tv_usec * 1000);
# Example 3: Compute Timestamp from Win32 `GetSystemTimeAsFileTime()`.
# FILETIME ft; GetSystemTimeAsFileTime(&ft); UINT64 ticks = (((UINT64)ft.
# dwHighDateTime) << 32) | ft.dwLowDateTime;
# // A Windows tick is 100 nanoseconds. Windows epoch 1601-01-01T00:00:00Z // is
# 11644473600 seconds before Unix epoch 1970-01-01T00:00:00Z. Timestamp
# timestamp; timestamp.set_seconds((INT64) ((ticks / 10000000) - 11644473600LL));
# timestamp.set_nanos((INT32) ((ticks % 10000000) * 100));
# Example 4: Compute Timestamp from Java `System.currentTimeMillis()`.
# long millis = System.currentTimeMillis();
# Timestamp timestamp = Timestamp.newBuilder().setSeconds(millis / 1000) .
# setNanos((int) ((millis % 1000) * 1000000)).build();
# Example 5: Compute Timestamp from current time in Python.
# timestamp = Timestamp() timestamp.GetCurrentTime()
# # JSON Mapping
# In JSON format, the Timestamp type is encoded as a string in the [RFC 3339](
# https://www.ietf.org/rfc/rfc3339.txt) format. That is, the format is "`year`-`
# month`-`day`T`hour`:`min`:`sec`[.`frac_sec`]Z" where `year` is always
# expressed using four digits while `month`, `day`, `hour`, `min`, and `sec` are
# zero-padded to two digits each. The fractional seconds, which can go up to 9
# digits (i.e. up to 1 nanosecond resolution), are optional. The "Z" suffix
# indicates the timezone ("UTC"); the timezone is required, though only UTC (as
# indicated by "Z") is currently supported.
# For example, "2017-01-15T01:30:15.01Z" encodes 15.01 seconds past 01:30 UTC on
# January 15, 2017.
# In JavaScript, one can convert a Date object to this format using the standard
# [toISOString()](https://developer.mozilla.org/en-US/docs/Web/JavaScript/
# Reference/Global_Objects/Date/toISOString] method. In Python, a standard `
# datetime.datetime` object can be converted to this format using [`strftime`](
# https://docs.python.org/2/library/time.html#time.strftime) with the time
# format spec '%Y-%m-%dT%H:%M:%S.%fZ'. Likewise, in Java, one can use the Joda
# Time's [`ISODateTimeFormat.dateTime()`]( http://www.joda.org/joda-time/apidocs/
# org/joda/time/format/ISODateTimeFormat.html#dateTime-- ) to obtain a formatter
# capable of generating timestamps in this format.
# Corresponds to the JSON property `completionTime`
# @return [Google::Apis::ToolresultsV1beta3::Timestamp]
attr_accessor :completion_time
# A Timestamp represents a point in time independent of any time zone or
# calendar, represented as seconds and fractions of seconds at nanosecond
# resolution in UTC Epoch time. It is encoded using the Proleptic Gregorian
# Calendar which extends the Gregorian calendar backwards to year one. It is
# encoded assuming all minutes are 60 seconds long, i.e. leap seconds are "
# smeared" so that no leap second table is needed for interpretation. Range is
# from 0001-01-01T00:00:00Z to 9999-12-31T23:59:59.999999999Z. By restricting to
# that range, we ensure that we can convert to and from RFC 3339 date strings.
# See [https://www.ietf.org/rfc/rfc3339.txt](https://www.ietf.org/rfc/rfc3339.
# txt).
# # Examples
# Example 1: Compute Timestamp from POSIX `time()`.
# Timestamp timestamp; timestamp.set_seconds(time(NULL)); timestamp.set_nanos(0);
# Example 2: Compute Timestamp from POSIX `gettimeofday()`.
# struct timeval tv; gettimeofday(&tv, NULL);
# Timestamp timestamp; timestamp.set_seconds(tv.tv_sec); timestamp.set_nanos(tv.
# tv_usec * 1000);
# Example 3: Compute Timestamp from Win32 `GetSystemTimeAsFileTime()`.
# FILETIME ft; GetSystemTimeAsFileTime(&ft); UINT64 ticks = (((UINT64)ft.
# dwHighDateTime) << 32) | ft.dwLowDateTime;
# // A Windows tick is 100 nanoseconds. Windows epoch 1601-01-01T00:00:00Z // is
# 11644473600 seconds before Unix epoch 1970-01-01T00:00:00Z. Timestamp
# timestamp; timestamp.set_seconds((INT64) ((ticks / 10000000) - 11644473600LL));
# timestamp.set_nanos((INT32) ((ticks % 10000000) * 100));
# Example 4: Compute Timestamp from Java `System.currentTimeMillis()`.
# long millis = System.currentTimeMillis();
# Timestamp timestamp = Timestamp.newBuilder().setSeconds(millis / 1000) .
# setNanos((int) ((millis % 1000) * 1000000)).build();
# Example 5: Compute Timestamp from current time in Python.
# timestamp = Timestamp() timestamp.GetCurrentTime()
# # JSON Mapping
# In JSON format, the Timestamp type is encoded as a string in the [RFC 3339](
# https://www.ietf.org/rfc/rfc3339.txt) format. That is, the format is "`year`-`
# month`-`day`T`hour`:`min`:`sec`[.`frac_sec`]Z" where `year` is always
# expressed using four digits while `month`, `day`, `hour`, `min`, and `sec` are
# zero-padded to two digits each. The fractional seconds, which can go up to 9
# digits (i.e. up to 1 nanosecond resolution), are optional. The "Z" suffix
# indicates the timezone ("UTC"); the timezone is required, though only UTC (as
# indicated by "Z") is currently supported.
# For example, "2017-01-15T01:30:15.01Z" encodes 15.01 seconds past 01:30 UTC on
# January 15, 2017.
# In JavaScript, one can convert a Date object to this format using the standard
# [toISOString()](https://developer.mozilla.org/en-US/docs/Web/JavaScript/
# Reference/Global_Objects/Date/toISOString] method. In Python, a standard `
# datetime.datetime` object can be converted to this format using [`strftime`](
# https://docs.python.org/2/library/time.html#time.strftime) with the time
# format spec '%Y-%m-%dT%H:%M:%S.%fZ'. Likewise, in Java, one can use the Joda
# Time's [`ISODateTimeFormat.dateTime()`]( http://www.joda.org/joda-time/apidocs/
# org/joda/time/format/ISODateTimeFormat.html#dateTime-- ) to obtain a formatter
# capable of generating timestamps in this format.
# Corresponds to the JSON property `creationTime`
# @return [Google::Apis::ToolresultsV1beta3::Timestamp]
attr_accessor :creation_time
# A description of this tool For example: mvn clean package -D skipTests=true
# - In response: present if set by create/update request - In create/update
# request: optional
# Corresponds to the JSON property `description`
# @return [String]
attr_accessor :description
# A Duration represents a signed, fixed-length span of time represented as a
# count of seconds and fractions of seconds at nanosecond resolution. It is
# independent of any calendar and concepts like "day" or "month". It is related
# to Timestamp in that the difference between two Timestamp values is a Duration
# and it can be added or subtracted from a Timestamp. Range is approximately +-
# 10,000 years.
# # Examples
# Example 1: Compute Duration from two Timestamps in pseudo code.
# Timestamp start = ...; Timestamp end = ...; Duration duration = ...;
# duration.seconds = end.seconds - start.seconds; duration.nanos = end.nanos -
# start.nanos;
# if (duration.seconds 0) ` duration.seconds += 1; duration.nanos -= 1000000000;
# ` else if (durations.seconds > 0 && duration.nanos < 0) ` duration.seconds -=
# 1; duration.nanos += 1000000000; `
# Example 2: Compute Timestamp from Timestamp + Duration in pseudo code.
# Timestamp start = ...; Duration duration = ...; Timestamp end = ...;
# end.seconds = start.seconds + duration.seconds; end.nanos = start.nanos +
# duration.nanos;
# if (end.nanos = 1000000000) ` end.seconds += 1; end.nanos -= 1000000000; `
# Example 3: Compute Duration from datetime.timedelta in Python.
# td = datetime.timedelta(days=3, minutes=10) duration = Duration() duration.
# FromTimedelta(td)
# # JSON Mapping
# In JSON format, the Duration type is encoded as a string rather than an object,
# where the string ends in the suffix "s" (indicating seconds) and is preceded
# by the number of seconds, with nanoseconds expressed as fractional seconds.
# For example, 3 seconds with 0 nanoseconds should be encoded in JSON format as "
# 3s", while 3 seconds and 1 nanosecond should be expressed in JSON format as "3.
# 000000001s", and 3 seconds and 1 microsecond should be expressed in JSON
# format as "3.000001s".
# Corresponds to the JSON property `deviceUsageDuration`
# @return [Google::Apis::ToolresultsV1beta3::Duration]
attr_accessor :device_usage_duration
# If the execution containing this step has any dimension_definition set, then
# this field allows the child to specify the values of the dimensions.
# The keys must exactly match the dimension_definition of the execution.
# For example, if the execution has `dimension_definition = ['attempt', 'device']
# ` then a step must define values for those dimensions, eg. `dimension_value = [
# 'attempt': '1', 'device': 'Nexus 6']`
# If a step does not participate in one dimension of the matrix, the value for
# that dimension should be empty string. For example, if one of the tests is
# executed by a runner which does not support retries, the step could have `
# dimension_value = ['attempt': '', 'device': 'Nexus 6']`
# If the step does not participate in any dimensions of the matrix, it may leave
# dimension_value unset.
# A PRECONDITION_FAILED will be returned if any of the keys do not exist in the
# dimension_definition of the execution.
# A PRECONDITION_FAILED will be returned if another step in this execution
# already has the same name and dimension_value, but differs on other data
# fields, for example, step field is different.
# A PRECONDITION_FAILED will be returned if dimension_value is set, and there is
# a dimension_definition in the execution which is not specified as one of the
# keys.
# - In response: present if set by create - In create request: optional - In
# update request: never set
# Corresponds to the JSON property `dimensionValue`
# @return [Array<Google::Apis::ToolresultsV1beta3::StepDimensionValueEntry>]
attr_accessor :dimension_value
# Whether any of the outputs of this step are images whose thumbnails can be
# fetched with ListThumbnails.
# - In response: always set - In create/update request: never set
# Corresponds to the JSON property `hasImages`
# @return [Boolean]
attr_accessor :has_images
alias_method :has_images?, :has_images
# Arbitrary user-supplied key/value pairs that are associated with the step.
# Users are responsible for managing the key namespace such that keys don't
# accidentally collide.
# An INVALID_ARGUMENT will be returned if the number of labels exceeds 100 or if
# the length of any of the keys or values exceeds 100 characters.
# - In response: always set - In create request: optional - In update request:
# optional; any new key/value pair will be added to the map, and any new value
# for an existing key will update that key's value
# Corresponds to the JSON property `labels`
# @return [Array<Google::Apis::ToolresultsV1beta3::StepLabelsEntry>]
attr_accessor :labels
# A short human-readable name to display in the UI. Maximum of 100 characters.
# For example: Clean build
# A PRECONDITION_FAILED will be returned upon creating a new step if it shares
# its name and dimension_value with an existing step. If two steps represent a
# similar action, but have different dimension values, they should share the
# same name. For instance, if the same set of tests is run on two different
# platforms, the two steps should have the same name.
# - In response: always set - In create request: always set - In update request:
# never set
# Corresponds to the JSON property `name`
# @return [String]
attr_accessor :name
# Interprets a result so that humans and machines can act on it.
# Corresponds to the JSON property `outcome`
# @return [Google::Apis::ToolresultsV1beta3::Outcome]
attr_accessor :outcome
# A Duration represents a signed, fixed-length span of time represented as a
# count of seconds and fractions of seconds at nanosecond resolution. It is
# independent of any calendar and concepts like "day" or "month". It is related
# to Timestamp in that the difference between two Timestamp values is a Duration
# and it can be added or subtracted from a Timestamp. Range is approximately +-
# 10,000 years.
# # Examples
# Example 1: Compute Duration from two Timestamps in pseudo code.
# Timestamp start = ...; Timestamp end = ...; Duration duration = ...;
# duration.seconds = end.seconds - start.seconds; duration.nanos = end.nanos -
# start.nanos;
# if (duration.seconds 0) ` duration.seconds += 1; duration.nanos -= 1000000000;
# ` else if (durations.seconds > 0 && duration.nanos < 0) ` duration.seconds -=
# 1; duration.nanos += 1000000000; `
# Example 2: Compute Timestamp from Timestamp + Duration in pseudo code.
# Timestamp start = ...; Duration duration = ...; Timestamp end = ...;
# end.seconds = start.seconds + duration.seconds; end.nanos = start.nanos +
# duration.nanos;
# if (end.nanos = 1000000000) ` end.seconds += 1; end.nanos -= 1000000000; `
# Example 3: Compute Duration from datetime.timedelta in Python.
# td = datetime.timedelta(days=3, minutes=10) duration = Duration() duration.
# FromTimedelta(td)
# # JSON Mapping
# In JSON format, the Duration type is encoded as a string rather than an object,
# where the string ends in the suffix "s" (indicating seconds) and is preceded
# by the number of seconds, with nanoseconds expressed as fractional seconds.
# For example, 3 seconds with 0 nanoseconds should be encoded in JSON format as "
# 3s", while 3 seconds and 1 nanosecond should be expressed in JSON format as "3.
# 000000001s", and 3 seconds and 1 microsecond should be expressed in JSON
# format as "3.000001s".
# Corresponds to the JSON property `runDuration`
# @return [Google::Apis::ToolresultsV1beta3::Duration]
attr_accessor :run_duration
# The initial state is IN_PROGRESS. The only legal state transitions are *
# IN_PROGRESS -> COMPLETE
# A PRECONDITION_FAILED will be returned if an invalid transition is requested.
# It is valid to create Step with a state set to COMPLETE. The state can only be
# set to COMPLETE once. A PRECONDITION_FAILED will be returned if the state is
# set to COMPLETE multiple times.
# - In response: always set - In create/update request: optional
# Corresponds to the JSON property `state`
# @return [String]
attr_accessor :state
# A unique identifier within a Execution for this Step.
# Returns INVALID_ARGUMENT if this field is set or overwritten by the caller.
# - In response: always set - In create/update request: never set
# Corresponds to the JSON property `stepId`
# @return [String]
attr_accessor :step_id
# A step that represents running tests.
# It accepts ant-junit xml files which will be parsed into structured test
# results by the service. Xml file paths are updated in order to append more
# files, however they can't be deleted.
# Users can also add test results manually by using the test_result field.
# Corresponds to the JSON property `testExecutionStep`
# @return [Google::Apis::ToolresultsV1beta3::TestExecutionStep]
attr_accessor :test_execution_step
# Generic tool step to be used for binaries we do not explicitly support. For
# example: running cp to copy artifacts from one location to another.
# Corresponds to the JSON property `toolExecutionStep`
# @return [Google::Apis::ToolresultsV1beta3::ToolExecutionStep]
attr_accessor :tool_execution_step
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@completion_time = args[:completion_time] if args.key?(:completion_time)
@creation_time = args[:creation_time] if args.key?(:creation_time)
@description = args[:description] if args.key?(:description)
@device_usage_duration = args[:device_usage_duration] if args.key?(:device_usage_duration)
@dimension_value = args[:dimension_value] if args.key?(:dimension_value)
@has_images = args[:has_images] if args.key?(:has_images)
@labels = args[:labels] if args.key?(:labels)
@name = args[:name] if args.key?(:name)
@outcome = args[:outcome] if args.key?(:outcome)
@run_duration = args[:run_duration] if args.key?(:run_duration)
@state = args[:state] if args.key?(:state)
@step_id = args[:step_id] if args.key?(:step_id)
@test_execution_step = args[:test_execution_step] if args.key?(:test_execution_step)
@tool_execution_step = args[:tool_execution_step] if args.key?(:tool_execution_step)
end
end
#
class StepDimensionValueEntry
include Google::Apis::Core::Hashable
#
# Corresponds to the JSON property `key`
# @return [String]
attr_accessor :key
#
# Corresponds to the JSON property `value`
# @return [String]
attr_accessor :value
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@key = args[:key] if args.key?(:key)
@value = args[:value] if args.key?(:value)
end
end
#
class StepLabelsEntry
include Google::Apis::Core::Hashable
#
# Corresponds to the JSON property `key`
# @return [String]
attr_accessor :key
#
# Corresponds to the JSON property `value`
# @return [String]
attr_accessor :value
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@key = args[:key] if args.key?(:key)
@value = args[:value] if args.key?(:value)
end
end
#
class SuccessDetail
include Google::Apis::Core::Hashable
# If a native process other than the app crashed.
# Corresponds to the JSON property `otherNativeCrash`
# @return [Boolean]
attr_accessor :other_native_crash
alias_method :other_native_crash?, :other_native_crash
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@other_native_crash = args[:other_native_crash] if args.key?(:other_native_crash)
end
end
# A reference to a test case.
# Test case references are canonically ordered lexicographically by these three
# factors: * First, by test_suite_name. * Second, by class_name. * Third, by
# name.
class TestCaseReference
include Google::Apis::Core::Hashable
# The name of the class.
# Corresponds to the JSON property `className`
# @return [String]
attr_accessor :class_name
# The name of the test case.
# Required.
# Corresponds to the JSON property `name`
# @return [String]
attr_accessor :name
# The name of the test suite to which this test case belongs.
# Corresponds to the JSON property `testSuiteName`
# @return [String]
attr_accessor :test_suite_name
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@class_name = args[:class_name] if args.key?(:class_name)
@name = args[:name] if args.key?(:name)
@test_suite_name = args[:test_suite_name] if args.key?(:test_suite_name)
end
end
# A step that represents running tests.
# It accepts ant-junit xml files which will be parsed into structured test
# results by the service. Xml file paths are updated in order to append more
# files, however they can't be deleted.
# Users can also add test results manually by using the test_result field.
class TestExecutionStep
include Google::Apis::Core::Hashable
# Issues observed during the test execution.
# For example, if the mobile app under test crashed during the test, the error
# message and the stack trace content can be recorded here to assist debugging.
# - In response: present if set by create or update - In create/update request:
# optional
# Corresponds to the JSON property `testIssues`
# @return [Array<Google::Apis::ToolresultsV1beta3::TestIssue>]
attr_accessor :test_issues
# List of test suite overview contents. This could be parsed from xUnit XML log
# by server, or uploaded directly by user. This references should only be called
# when test suites are fully parsed or uploaded.
# The maximum allowed number of test suite overviews per step is 1000.
# - In response: always set - In create request: optional - In update request:
# never (use publishXunitXmlFiles custom method instead)
# Corresponds to the JSON property `testSuiteOverviews`
# @return [Array<Google::Apis::ToolresultsV1beta3::TestSuiteOverview>]
attr_accessor :test_suite_overviews
# Testing timing break down to know phases.
# Corresponds to the JSON property `testTiming`
# @return [Google::Apis::ToolresultsV1beta3::TestTiming]
attr_accessor :test_timing
# An execution of an arbitrary tool. It could be a test runner or a tool copying
# artifacts or deploying code.
# Corresponds to the JSON property `toolExecution`
# @return [Google::Apis::ToolresultsV1beta3::ToolExecution]
attr_accessor :tool_execution
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@test_issues = args[:test_issues] if args.key?(:test_issues)
@test_suite_overviews = args[:test_suite_overviews] if args.key?(:test_suite_overviews)
@test_timing = args[:test_timing] if args.key?(:test_timing)
@tool_execution = args[:tool_execution] if args.key?(:tool_execution)
end
end
# An issue detected occurring during a test execution.
class TestIssue
include Google::Apis::Core::Hashable
# A brief human-readable message describing the issue. Required.
# Corresponds to the JSON property `errorMessage`
# @return [String]
attr_accessor :error_message
# Severity of issue. Required.
# Corresponds to the JSON property `severity`
# @return [String]
attr_accessor :severity
# A stacktrace.
# Corresponds to the JSON property `stackTrace`
# @return [Google::Apis::ToolresultsV1beta3::StackTrace]
attr_accessor :stack_trace
# Type of issue. Required.
# Corresponds to the JSON property `type`
# @return [String]
attr_accessor :type
# `Any` contains an arbitrary serialized protocol buffer message along with a
# URL that describes the type of the serialized message.
# Protobuf library provides support to pack/unpack Any values in the form of
# utility functions or additional generated methods of the Any type.
# Example 1: Pack and unpack a message in C++.
# Foo foo = ...; Any any; any.PackFrom(foo); ... if (any.UnpackTo(&foo)) ` ... `
# Example 2: Pack and unpack a message in Java.
# Foo foo = ...; Any any = Any.pack(foo); ... if (any.is(Foo.class)) ` foo = any.
# unpack(Foo.class); `
# Example 3: Pack and unpack a message in Python.
# foo = Foo(...) any = Any() any.Pack(foo) ... if any.Is(Foo.DESCRIPTOR): any.
# Unpack(foo) ...
# Example 4: Pack and unpack a message in Go
# foo := &pb.Foo`...` any, err := ptypes.MarshalAny(foo) ... foo := &pb.Foo`` if
# err := ptypes.UnmarshalAny(any, foo); err != nil ` ... `
# The pack methods provided by protobuf library will by default use 'type.
# googleapis.com/full.type.name' as the type URL and the unpack methods only use
# the fully qualified type name after the last '/' in the type URL, for example "
# foo.bar.com/x/y.z" will yield type name "y.z".
# JSON ==== The JSON representation of an `Any` value uses the regular
# representation of the deserialized, embedded message, with an additional field
# `@type` which contains the type URL. Example:
# package google.profile; message Person ` string first_name = 1; string
# last_name = 2; `
# ` "@type": "type.googleapis.com/google.profile.Person", "firstName": , "
# lastName": `
# If the embedded message type is well-known and has a custom JSON
# representation, that representation will be embedded adding a field `value`
# which holds the custom JSON in addition to the `@type` field. Example (for
# message [google.protobuf.Duration][]):
# ` "@type": "type.googleapis.com/google.protobuf.Duration", "value": "1.212s" `
# Corresponds to the JSON property `warning`
# @return [Google::Apis::ToolresultsV1beta3::Any]
attr_accessor :warning
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@error_message = args[:error_message] if args.key?(:error_message)
@severity = args[:severity] if args.key?(:severity)
@stack_trace = args[:stack_trace] if args.key?(:stack_trace)
@type = args[:type] if args.key?(:type)
@warning = args[:warning] if args.key?(:warning)
end
end
# A summary of a test suite result either parsed from XML or uploaded directly
# by a user.
# Note: the API related comments are for StepService only. This message is also
# being used in ExecutionService in a read only mode for the corresponding step.
class TestSuiteOverview
include Google::Apis::Core::Hashable
# Number of test cases in error, typically set by the service by parsing the
# xml_source.
# - In create/response: always set - In update request: never
# Corresponds to the JSON property `errorCount`
# @return [Fixnum]
attr_accessor :error_count
# Number of failed test cases, typically set by the service by parsing the
# xml_source. May also be set by the user.
# - In create/response: always set - In update request: never
# Corresponds to the JSON property `failureCount`
# @return [Fixnum]
attr_accessor :failure_count
# The name of the test suite.
# - In create/response: always set - In update request: never
# Corresponds to the JSON property `name`
# @return [String]
attr_accessor :name
# Number of test cases not run, typically set by the service by parsing the
# xml_source.
# - In create/response: always set - In update request: never
# Corresponds to the JSON property `skippedCount`
# @return [Fixnum]
attr_accessor :skipped_count
# Number of test cases, typically set by the service by parsing the xml_source.
# - In create/response: always set - In update request: never
# Corresponds to the JSON property `totalCount`
# @return [Fixnum]
attr_accessor :total_count
# A reference to a file.
# Corresponds to the JSON property `xmlSource`
# @return [Google::Apis::ToolresultsV1beta3::FileReference]
attr_accessor :xml_source
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@error_count = args[:error_count] if args.key?(:error_count)
@failure_count = args[:failure_count] if args.key?(:failure_count)
@name = args[:name] if args.key?(:name)
@skipped_count = args[:skipped_count] if args.key?(:skipped_count)
@total_count = args[:total_count] if args.key?(:total_count)
@xml_source = args[:xml_source] if args.key?(:xml_source)
end
end
# Testing timing break down to know phases.
class TestTiming
include Google::Apis::Core::Hashable
# A Duration represents a signed, fixed-length span of time represented as a
# count of seconds and fractions of seconds at nanosecond resolution. It is
# independent of any calendar and concepts like "day" or "month". It is related
# to Timestamp in that the difference between two Timestamp values is a Duration
# and it can be added or subtracted from a Timestamp. Range is approximately +-
# 10,000 years.
# # Examples
# Example 1: Compute Duration from two Timestamps in pseudo code.
# Timestamp start = ...; Timestamp end = ...; Duration duration = ...;
# duration.seconds = end.seconds - start.seconds; duration.nanos = end.nanos -
# start.nanos;
# if (duration.seconds 0) ` duration.seconds += 1; duration.nanos -= 1000000000;
# ` else if (durations.seconds > 0 && duration.nanos < 0) ` duration.seconds -=
# 1; duration.nanos += 1000000000; `
# Example 2: Compute Timestamp from Timestamp + Duration in pseudo code.
# Timestamp start = ...; Duration duration = ...; Timestamp end = ...;
# end.seconds = start.seconds + duration.seconds; end.nanos = start.nanos +
# duration.nanos;
# if (end.nanos = 1000000000) ` end.seconds += 1; end.nanos -= 1000000000; `
# Example 3: Compute Duration from datetime.timedelta in Python.
# td = datetime.timedelta(days=3, minutes=10) duration = Duration() duration.
# FromTimedelta(td)
# # JSON Mapping
# In JSON format, the Duration type is encoded as a string rather than an object,
# where the string ends in the suffix "s" (indicating seconds) and is preceded
# by the number of seconds, with nanoseconds expressed as fractional seconds.
# For example, 3 seconds with 0 nanoseconds should be encoded in JSON format as "
# 3s", while 3 seconds and 1 nanosecond should be expressed in JSON format as "3.
# 000000001s", and 3 seconds and 1 microsecond should be expressed in JSON
# format as "3.000001s".
# Corresponds to the JSON property `testProcessDuration`
# @return [Google::Apis::ToolresultsV1beta3::Duration]
attr_accessor :test_process_duration
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@test_process_duration = args[:test_process_duration] if args.key?(:test_process_duration)
end
end
# A single thumbnail, with its size and format.
class Thumbnail
include Google::Apis::Core::Hashable
# The thumbnail's content type, i.e. "image/png".
# Always set.
# Corresponds to the JSON property `contentType`
# @return [String]
attr_accessor :content_type
# The thumbnail file itself.
# That is, the bytes here are precisely the bytes that make up the thumbnail
# file; they can be served as an image as-is (with the appropriate content type.)
# Always set.
# Corresponds to the JSON property `data`
# NOTE: Values are automatically base64 encoded/decoded in the client library.
# @return [String]
attr_accessor :data
# The height of the thumbnail, in pixels.
# Always set.
# Corresponds to the JSON property `heightPx`
# @return [Fixnum]
attr_accessor :height_px
# The width of the thumbnail, in pixels.
# Always set.
# Corresponds to the JSON property `widthPx`
# @return [Fixnum]
attr_accessor :width_px
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@content_type = args[:content_type] if args.key?(:content_type)
@data = args[:data] if args.key?(:data)
@height_px = args[:height_px] if args.key?(:height_px)
@width_px = args[:width_px] if args.key?(:width_px)
end
end
# A Timestamp represents a point in time independent of any time zone or
# calendar, represented as seconds and fractions of seconds at nanosecond
# resolution in UTC Epoch time. It is encoded using the Proleptic Gregorian
# Calendar which extends the Gregorian calendar backwards to year one. It is
# encoded assuming all minutes are 60 seconds long, i.e. leap seconds are "
# smeared" so that no leap second table is needed for interpretation. Range is
# from 0001-01-01T00:00:00Z to 9999-12-31T23:59:59.999999999Z. By restricting to
# that range, we ensure that we can convert to and from RFC 3339 date strings.
# See [https://www.ietf.org/rfc/rfc3339.txt](https://www.ietf.org/rfc/rfc3339.
# txt).
# # Examples
# Example 1: Compute Timestamp from POSIX `time()`.
# Timestamp timestamp; timestamp.set_seconds(time(NULL)); timestamp.set_nanos(0);
# Example 2: Compute Timestamp from POSIX `gettimeofday()`.
# struct timeval tv; gettimeofday(&tv, NULL);
# Timestamp timestamp; timestamp.set_seconds(tv.tv_sec); timestamp.set_nanos(tv.
# tv_usec * 1000);
# Example 3: Compute Timestamp from Win32 `GetSystemTimeAsFileTime()`.
# FILETIME ft; GetSystemTimeAsFileTime(&ft); UINT64 ticks = (((UINT64)ft.
# dwHighDateTime) << 32) | ft.dwLowDateTime;
# // A Windows tick is 100 nanoseconds. Windows epoch 1601-01-01T00:00:00Z // is
# 11644473600 seconds before Unix epoch 1970-01-01T00:00:00Z. Timestamp
# timestamp; timestamp.set_seconds((INT64) ((ticks / 10000000) - 11644473600LL));
# timestamp.set_nanos((INT32) ((ticks % 10000000) * 100));
# Example 4: Compute Timestamp from Java `System.currentTimeMillis()`.
# long millis = System.currentTimeMillis();
# Timestamp timestamp = Timestamp.newBuilder().setSeconds(millis / 1000) .
# setNanos((int) ((millis % 1000) * 1000000)).build();
# Example 5: Compute Timestamp from current time in Python.
# timestamp = Timestamp() timestamp.GetCurrentTime()
# # JSON Mapping
# In JSON format, the Timestamp type is encoded as a string in the [RFC 3339](
# https://www.ietf.org/rfc/rfc3339.txt) format. That is, the format is "`year`-`
# month`-`day`T`hour`:`min`:`sec`[.`frac_sec`]Z" where `year` is always
# expressed using four digits while `month`, `day`, `hour`, `min`, and `sec` are
# zero-padded to two digits each. The fractional seconds, which can go up to 9
# digits (i.e. up to 1 nanosecond resolution), are optional. The "Z" suffix
# indicates the timezone ("UTC"); the timezone is required, though only UTC (as
# indicated by "Z") is currently supported.
# For example, "2017-01-15T01:30:15.01Z" encodes 15.01 seconds past 01:30 UTC on
# January 15, 2017.
# In JavaScript, one can convert a Date object to this format using the standard
# [toISOString()](https://developer.mozilla.org/en-US/docs/Web/JavaScript/
# Reference/Global_Objects/Date/toISOString] method. In Python, a standard `
# datetime.datetime` object can be converted to this format using [`strftime`](
# https://docs.python.org/2/library/time.html#time.strftime) with the time
# format spec '%Y-%m-%dT%H:%M:%S.%fZ'. Likewise, in Java, one can use the Joda
# Time's [`ISODateTimeFormat.dateTime()`]( http://www.joda.org/joda-time/apidocs/
# org/joda/time/format/ISODateTimeFormat.html#dateTime-- ) to obtain a formatter
# capable of generating timestamps in this format.
class Timestamp
include Google::Apis::Core::Hashable
# Non-negative fractions of a second at nanosecond resolution. Negative second
# values with fractions must still have non-negative nanos values that count
# forward in time. Must be from 0 to 999,999,999 inclusive.
# Corresponds to the JSON property `nanos`
# @return [Fixnum]
attr_accessor :nanos
# Represents seconds of UTC time since Unix epoch 1970-01-01T00:00:00Z. Must be
# from 0001-01-01T00:00:00Z to 9999-12-31T23:59:59Z inclusive.
# Corresponds to the JSON property `seconds`
# @return [Fixnum]
attr_accessor :seconds
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@nanos = args[:nanos] if args.key?(:nanos)
@seconds = args[:seconds] if args.key?(:seconds)
end
end
# An execution of an arbitrary tool. It could be a test runner or a tool copying
# artifacts or deploying code.
class ToolExecution
include Google::Apis::Core::Hashable
# The full tokenized command line including the program name (equivalent to argv
# in a C program).
# - In response: present if set by create request - In create request: optional -
# In update request: never set
# Corresponds to the JSON property `commandLineArguments`
# @return [Array<String>]
attr_accessor :command_line_arguments
# Exit code from a tool execution.
# Corresponds to the JSON property `exitCode`
# @return [Google::Apis::ToolresultsV1beta3::ToolExitCode]
attr_accessor :exit_code
# References to any plain text logs output the tool execution.
# This field can be set before the tool has exited in order to be able to have
# access to a live view of the logs while the tool is running.
# The maximum allowed number of tool logs per step is 1000.
# - In response: present if set by create/update request - In create request:
# optional - In update request: optional, any value provided will be appended to
# the existing list
# Corresponds to the JSON property `toolLogs`
# @return [Array<Google::Apis::ToolresultsV1beta3::FileReference>]
attr_accessor :tool_logs
# References to opaque files of any format output by the tool execution.
# The maximum allowed number of tool outputs per step is 1000.
# - In response: present if set by create/update request - In create request:
# optional - In update request: optional, any value provided will be appended to
# the existing list
# Corresponds to the JSON property `toolOutputs`
# @return [Array<Google::Apis::ToolresultsV1beta3::ToolOutputReference>]
attr_accessor :tool_outputs
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@command_line_arguments = args[:command_line_arguments] if args.key?(:command_line_arguments)
@exit_code = args[:exit_code] if args.key?(:exit_code)
@tool_logs = args[:tool_logs] if args.key?(:tool_logs)
@tool_outputs = args[:tool_outputs] if args.key?(:tool_outputs)
end
end
# Generic tool step to be used for binaries we do not explicitly support. For
# example: running cp to copy artifacts from one location to another.
class ToolExecutionStep
include Google::Apis::Core::Hashable
# An execution of an arbitrary tool. It could be a test runner or a tool copying
# artifacts or deploying code.
# Corresponds to the JSON property `toolExecution`
# @return [Google::Apis::ToolresultsV1beta3::ToolExecution]
attr_accessor :tool_execution
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@tool_execution = args[:tool_execution] if args.key?(:tool_execution)
end
end
# Exit code from a tool execution.
class ToolExitCode
include Google::Apis::Core::Hashable
# Tool execution exit code. A value of 0 means that the execution was successful.
# - In response: always set - In create/update request: always set
# Corresponds to the JSON property `number`
# @return [Fixnum]
attr_accessor :number
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@number = args[:number] if args.key?(:number)
end
end
# A reference to a ToolExecution output file.
class ToolOutputReference
include Google::Apis::Core::Hashable
# A Timestamp represents a point in time independent of any time zone or
# calendar, represented as seconds and fractions of seconds at nanosecond
# resolution in UTC Epoch time. It is encoded using the Proleptic Gregorian
# Calendar which extends the Gregorian calendar backwards to year one. It is
# encoded assuming all minutes are 60 seconds long, i.e. leap seconds are "
# smeared" so that no leap second table is needed for interpretation. Range is
# from 0001-01-01T00:00:00Z to 9999-12-31T23:59:59.999999999Z. By restricting to
# that range, we ensure that we can convert to and from RFC 3339 date strings.
# See [https://www.ietf.org/rfc/rfc3339.txt](https://www.ietf.org/rfc/rfc3339.
# txt).
# # Examples
# Example 1: Compute Timestamp from POSIX `time()`.
# Timestamp timestamp; timestamp.set_seconds(time(NULL)); timestamp.set_nanos(0);
# Example 2: Compute Timestamp from POSIX `gettimeofday()`.
# struct timeval tv; gettimeofday(&tv, NULL);
# Timestamp timestamp; timestamp.set_seconds(tv.tv_sec); timestamp.set_nanos(tv.
# tv_usec * 1000);
# Example 3: Compute Timestamp from Win32 `GetSystemTimeAsFileTime()`.
# FILETIME ft; GetSystemTimeAsFileTime(&ft); UINT64 ticks = (((UINT64)ft.
# dwHighDateTime) << 32) | ft.dwLowDateTime;
# // A Windows tick is 100 nanoseconds. Windows epoch 1601-01-01T00:00:00Z // is
# 11644473600 seconds before Unix epoch 1970-01-01T00:00:00Z. Timestamp
# timestamp; timestamp.set_seconds((INT64) ((ticks / 10000000) - 11644473600LL));
# timestamp.set_nanos((INT32) ((ticks % 10000000) * 100));
# Example 4: Compute Timestamp from Java `System.currentTimeMillis()`.
# long millis = System.currentTimeMillis();
# Timestamp timestamp = Timestamp.newBuilder().setSeconds(millis / 1000) .
# setNanos((int) ((millis % 1000) * 1000000)).build();
# Example 5: Compute Timestamp from current time in Python.
# timestamp = Timestamp() timestamp.GetCurrentTime()
# # JSON Mapping
# In JSON format, the Timestamp type is encoded as a string in the [RFC 3339](
# https://www.ietf.org/rfc/rfc3339.txt) format. That is, the format is "`year`-`
# month`-`day`T`hour`:`min`:`sec`[.`frac_sec`]Z" where `year` is always
# expressed using four digits while `month`, `day`, `hour`, `min`, and `sec` are
# zero-padded to two digits each. The fractional seconds, which can go up to 9
# digits (i.e. up to 1 nanosecond resolution), are optional. The "Z" suffix
# indicates the timezone ("UTC"); the timezone is required, though only UTC (as
# indicated by "Z") is currently supported.
# For example, "2017-01-15T01:30:15.01Z" encodes 15.01 seconds past 01:30 UTC on
# January 15, 2017.
# In JavaScript, one can convert a Date object to this format using the standard
# [toISOString()](https://developer.mozilla.org/en-US/docs/Web/JavaScript/
# Reference/Global_Objects/Date/toISOString] method. In Python, a standard `
# datetime.datetime` object can be converted to this format using [`strftime`](
# https://docs.python.org/2/library/time.html#time.strftime) with the time
# format spec '%Y-%m-%dT%H:%M:%S.%fZ'. Likewise, in Java, one can use the Joda
# Time's [`ISODateTimeFormat.dateTime()`]( http://www.joda.org/joda-time/apidocs/
# org/joda/time/format/ISODateTimeFormat.html#dateTime-- ) to obtain a formatter
# capable of generating timestamps in this format.
# Corresponds to the JSON property `creationTime`
# @return [Google::Apis::ToolresultsV1beta3::Timestamp]
attr_accessor :creation_time
# A reference to a file.
# Corresponds to the JSON property `output`
# @return [Google::Apis::ToolresultsV1beta3::FileReference]
attr_accessor :output
# A reference to a test case.
# Test case references are canonically ordered lexicographically by these three
# factors: * First, by test_suite_name. * Second, by class_name. * Third, by
# name.
# Corresponds to the JSON property `testCase`
# @return [Google::Apis::ToolresultsV1beta3::TestCaseReference]
attr_accessor :test_case
def initialize(**args)
update!(**args)
end
# Update properties of this object
def update!(**args)
@creation_time = args[:creation_time] if args.key?(:creation_time)
@output = args[:output] if args.key?(:output)
@test_case = args[:test_case] if args.key?(:test_case)
end
end
end
end
end