Google Cloud Stackdriver 和 IoTDB 集成
这不是实时大规模查询的推荐配置。为了获得查询和压缩优化、高速摄取和高可用性,您可能需要考虑 Stackdriver 和 InfluxDB。
50 亿 +
Telegraf 下载量
#1
时序数据库
来源:DB Engines
10 亿 +
InfluxDB 下载量
2,800+
贡献者
目录
输入和输出集成概述
此插件支持通过 Stackdriver Monitoring API 从 Google Cloud 服务收集监控数据。它旨在通过收集相关指标来帮助用户监控其云基础设施的性能和健康状况。
此插件将 Telegraf 指标保存到 Apache IoTDB 后端,支持会话连接和数据插入。
集成详情
Google Cloud Stackdriver
Stackdriver Telegraf 插件允许用户使用 Cloud Monitoring API v3 从 Google Cloud Monitoring 查询时序数据。借助此插件,用户可以轻松地将 Google Cloud 监控指标集成到其监控堆栈中。此 API 提供了有关 Google Cloud 中运行的资源和应用程序的丰富见解,包括性能、正常运行时间和运营指标。该插件支持各种配置选项来过滤和优化检索到的数据,使用户能够根据其特定需求自定义其监控设置。此集成有助于更顺畅地维护云资源的健康和性能,并协助团队根据历史和当前性能统计数据做出数据驱动的决策。
IoTDB
Apache IoTDB(物联网数据库)是一种物联网原生数据库,具有用于数据管理和分析的高性能,可部署在边缘和云端。其轻量级架构、高性能和丰富的功能集非常适合物联网工业领域中的海量数据存储、高速数据摄取和复杂分析。IoTDB 与 Apache Hadoop、Spark 和 Flink 深度集成,进一步增强了其处理大规模数据和复杂处理任务的能力。
配置
Google Cloud Stackdriver
[[inputs.stackdriver]]
## GCP Project
project = "erudite-bloom-151019"
## Include timeseries that start with the given metric type.
metric_type_prefix_include = [
"compute.googleapis.com/",
]
## Exclude timeseries that start with the given metric type.
# metric_type_prefix_exclude = []
## Most metrics are updated no more than once per minute; it is recommended
## to override the agent level interval with a value of 1m or greater.
interval = "1m"
## Maximum number of API calls to make per second. The quota for accounts
## varies, it can be viewed on the API dashboard:
## https://cloud.google.com/monitoring/quotas#quotas_and_limits
# rate_limit = 14
## The delay and window options control the number of points selected on
## each gather. When set, metrics are gathered between:
## start: now() - delay - window
## end: now() - delay
#
## Collection delay; if set too low metrics may not yet be available.
# delay = "5m"
#
## If unset, the window will start at 1m and be updated dynamically to span
## the time between calls (approximately the length of the plugin interval).
# window = "1m"
## TTL for cached list of metric types. This is the maximum amount of time
## it may take to discover new metrics.
# cache_ttl = "1h"
## If true, raw bucket counts are collected for distribution value types.
## For a more lightweight collection, you may wish to disable and use
## distribution_aggregation_aligners instead.
# gather_raw_distribution_buckets = true
## Aggregate functions to be used for metrics whose value type is
## distribution. These aggregate values are recorded in in addition to raw
## bucket counts; if they are enabled.
##
## For a list of aligner strings see:
## https://cloud.google.com/monitoring/api/ref_v3/rpc/google.monitoring.v3#aligner
# distribution_aggregation_aligners = [
# "ALIGN_PERCENTILE_99",
# "ALIGN_PERCENTILE_95",
# "ALIGN_PERCENTILE_50",
# ]
## Filters can be added to reduce the number of time series matched. All
## functions are supported: starts_with, ends_with, has_substring, and
## one_of. Only the '=' operator is supported.
##
## The logical operators when combining filters are defined statically using
## the following values:
## filter ::= {AND AND AND }
## resource_labels ::= {OR }
## metric_labels ::= {OR }
## user_labels ::= {OR }
## system_labels ::= {OR }
##
## For more details, see https://cloud.google.com/monitoring/api/v3/filters
#
## Resource labels refine the time series selection with the following expression:
## resource.labels. =
# [[inputs.stackdriver.filter.resource_labels]]
# key = "instance_name"
# value = 'starts_with("localhost")'
#
## Metric labels refine the time series selection with the following expression:
## metric.labels. =
# [[inputs.stackdriver.filter.metric_labels]]
# key = "device_name"
# value = 'one_of("sda", "sdb")'
#
## User labels refine the time series selection with the following expression:
## metadata.user_labels."" =
# [[inputs.stackdriver.filter.user_labels]]
# key = "environment"
# value = 'one_of("prod", "staging")'
#
## System labels refine the time series selection with the following expression:
## metadata.system_labels."" =
# [[inputs.stackdriver.filter.system_labels]]
# key = "machine_type"
# value = 'starts_with("e2-")'
</code></pre>
IoTDB
[[outputs.iotdb]]
## Configuration of IoTDB server connection
host = "127.0.0.1"
# port = "6667"
## Configuration of authentication
# user = "root"
# password = "root"
## Timeout to open a new session.
## A value of zero means no timeout.
# timeout = "5s"
## Configuration of type conversion for 64-bit unsigned int
## IoTDB currently DOES NOT support unsigned integers (version 13.x).
## 32-bit unsigned integers are safely converted into 64-bit signed integers by the plugin,
## however, this is not true for 64-bit values in general as overflows may occur.
## The following setting allows to specify the handling of 64-bit unsigned integers.
## Available values are:
## - "int64" -- convert to 64-bit signed integers and accept overflows
## - "int64_clip" -- convert to 64-bit signed integers and clip the values on overflow to 9,223,372,036,854,775,807
## - "text" -- convert to the string representation of the value
# uint64_conversion = "int64_clip"
## Configuration of TimeStamp
## TimeStamp is always saved in 64bits int. timestamp_precision specifies the unit of timestamp.
## Available value:
## "second", "millisecond", "microsecond", "nanosecond"(default)
# timestamp_precision = "nanosecond"
## Handling of tags
## Tags are not fully supported by IoTDB.
## A guide with suggestions on how to handle tags can be found here:
## https://iotdb.apache.org/UserGuide/Master/API/InfluxDB-Protocol.html
##
## Available values are:
## - "fields" -- convert tags to fields in the measurement
## - "device_id" -- attach tags to the device ID
##
## For Example, a metric named "root.sg.device" with the tags `tag1: "private"` and `tag2: "working"` and
## fields `s1: 100` and `s2: "hello"` will result in the following representations in IoTDB
## - "fields" -- root.sg.device, s1=100, s2="hello", tag1="private", tag2="working"
## - "device_id" -- root.sg.device.private.working, s1=100, s2="hello"
# convert_tags_to = "device_id"
## Handling of unsupported characters
## Some characters in different versions of IoTDB are not supported in path name
## A guide with suggetions on valid paths can be found here:
## for iotdb 0.13.x -> https://iotdb.apache.org/UserGuide/V0.13.x/Reference/Syntax-Conventions.html#identifiers
## for iotdb 1.x.x and above -> https://iotdb.apache.org/UserGuide/V1.3.x/User-Manual/Syntax-Rule.html#identifier
##
## Available values are:
## - "1.0", "1.1", "1.2", "1.3" -- enclose in `` the world having forbidden character
## such as @ $ # : [ ] { } ( ) space
## - "0.13" -- enclose in `` the world having forbidden character
## such as space
##
## Keep this section commented if you don't want to sanitize the path
# sanitize_tag = "1.3"
输入和输出集成示例
Google Cloud Stackdriver
-
将云指标集成到自定义仪表板中:借助此插件,团队可以将 Google Cloud 的指标导入到个性化仪表板中,从而实现应用程序性能和资源利用率的实时监控。通过自定义云指标的可视化表示,运营团队可以轻松识别趋势和异常情况,从而在问题升级之前进行主动管理。
-
自动化警报和分析:用户可以设置自动化警报机制,利用插件的指标来跟踪资源阈值。此功能使团队能够通过提供即时通知来快速响应性能下降或中断,从而缩短平均恢复时间并确保持续的运营效率。
-
跨平台资源比较:该插件可用于从各种 Google Cloud 服务中提取指标,并将它们与本地资源进行比较。这种跨平台可见性帮助组织就资源分配和扩展策略做出明智的决策,并优化云支出与本地基础设施。
-
用于容量规划的历史数据分析:通过随时间推移收集历史指标,该插件使团队能够进行彻底的容量规划。了解过去的性能趋势有助于准确预测资源需求,从而更好地进行预算和投资策略。
IoTDB
-
实时物联网监控:利用 IoTDB 插件从各种物联网设备收集传感器数据,并将其保存在 Apache IoTDB 后端,从而实现对环境条件(如温度和湿度)的实时监控。此用例使组织能够分析随时间推移的趋势并根据历史数据做出明智的决策,同时还利用 IoTDB 的高效存储和查询功能。
-
智能农业数据收集:使用 IoTDB 插件从部署在田地中的智能农业传感器收集指标。通过将湿度水平、养分含量和大气条件传输到 IoTDB,农民可以访问有关最佳种植和浇水计划的详细见解,从而提高作物产量和资源管理水平。
-
能源消耗分析:利用 IoTDB 插件跟踪整个公用事业网络中智能电表的能源消耗指标。此集成支持分析以识别使用高峰并预测未来的消耗模式,最终支持节能措施和改进的公用事业管理。
-
自动化工业设备监控:使用此插件从制造工厂的机器中收集运营指标,并将它们存储在 IoTDB 中进行分析。此设置可以帮助识别效率低下、预测性维护需求和运营异常,确保最佳性能并最大限度地减少意外停机时间。
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