对于大规模实时查询,这不是推荐的配置。 为了查询和压缩优化、高速摄取和高可用性,您可能需要考虑 gNMI 和 InfluxDB。
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时间序列数据库
来源:DB Engines
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目录
强大的性能,无限的扩展
收集、组织和处理海量高速数据。当您将任何数据视为时间序列数据时,它都更有价值。 借助 InfluxDB,排名第一的时间序列平台,它旨在与 Telegraf 一起扩展。
查看入门方法
输入和输出集成概述
gNMI(gRPC 网络管理接口)输入插件使用 gNMI Subscribe 方法从网络设备收集遥测数据。 它支持 TLS 以实现安全身份验证和数据传输。
Telegraf 的 SQL 插件有助于将指标存储在 SQL 数据库中。 当配置为 Microsoft SQL Server 时,它支持特定的 DSN 格式和架构要求,从而可以与 SQL Server 无缝集成。
集成详情
gNMI
此输入插件与供应商无关,可以与任何支持 gNMI 规范的平台一起使用。 它基于 gNMI Subscribe 方法消耗遥测数据,从而可以实时监控网络设备。
Microsoft SQL Server
Telegraf 用于 Microsoft SQL Server 的 SQL 输出插件旨在通过动态创建与传入数据结构匹配的表和列来捕获和存储指标数据。 此集成利用 go-mssqldb 驱动程序,该驱动程序通过包含服务器、端口和数据库详细信息的 DSN 遵循 SQL Server 连接协议。 尽管由于单元测试有限,该驱动程序被认为是实验性的,但它为动态模式生成和数据插入提供了强大的支持,从而可以详细记录系统性能的时间戳记录。 尽管其状态为实验性,但这种灵活性使其成为需要可靠且精细的指标日志记录的环境的宝贵工具。
配置
gNMI
[[inputs.gnmi]]
## Address and port of the gNMI GRPC server
addresses = ["10.49.234.114:57777"]
## define credentials
username = "cisco"
password = "cisco"
## gNMI encoding requested (one of: "proto", "json", "json_ietf", "bytes")
# encoding = "proto"
## redial in case of failures after
# redial = "10s"
## gRPC Keepalive settings
## See https://pkg.go.dev/google.golang.org/grpc/keepalive
## The client will ping the server to see if the transport is still alive if it has
## not see any activity for the given time.
## If not set, none of the keep-alive setting (including those below) will be applied.
## If set and set below 10 seconds, the gRPC library will apply a minimum value of 10s will be used instead.
# keepalive_time = ""
## Timeout for seeing any activity after the keep-alive probe was
## sent. If no activity is seen the connection is closed.
# keepalive_timeout = ""
## gRPC Maximum Message Size
# max_msg_size = "4MB"
## Enable to get the canonical path as field-name
# canonical_field_names = false
## Remove leading slashes and dots in field-name
# trim_field_names = false
## Guess the path-tag if an update does not contain a prefix-path
## Supported values are
## none -- do not add a 'path' tag
## common path -- use the common path elements of all fields in an update
## subscription -- use the subscription path
# path_guessing_strategy = "none"
## Prefix tags from path keys with the path element
# prefix_tag_key_with_path = false
## Optional client-side TLS to authenticate the device
## Set to true/false to enforce TLS being enabled/disabled. If not set,
## enable TLS only if any of the other options are specified.
# tls_enable =
## Trusted root certificates for server
# tls_ca = "/path/to/cafile"
## Used for TLS client certificate authentication
# tls_cert = "/path/to/certfile"
## Used for TLS client certificate authentication
# tls_key = "/path/to/keyfile"
## Password for the key file if it is encrypted
# tls_key_pwd = ""
## Send the specified TLS server name via SNI
# tls_server_name = "kubernetes.example.com"
## Minimal TLS version to accept by the client
# tls_min_version = "TLS12"
## List of ciphers to accept, by default all secure ciphers will be accepted
## See https://pkg.go.dev/crypto/tls#pkg-constants for supported values.
## Use "all", "secure" and "insecure" to add all support ciphers, secure
## suites or insecure suites respectively.
# tls_cipher_suites = ["secure"]
## Renegotiation method, "never", "once" or "freely"
# tls_renegotiation_method = "never"
## Use TLS but skip chain & host verification
# insecure_skip_verify = false
## gNMI subscription prefix (optional, can usually be left empty)
## See: https://github.com/openconfig/reference/blob/master/rpc/gnmi/gnmi-specification.md#222-paths
# origin = ""
# prefix = ""
# target = ""
## Vendor specific options
## This defines what vendor specific options to load.
## * Juniper Header Extension (juniper_header): some sensors are directly managed by
## Linecard, which adds the Juniper GNMI Header Extension. Enabling this
## allows the decoding of the Extension header if present. Currently this knob
## adds component, component_id & sub_component_id as additional tags
# vendor_specific = []
## YANG model paths for decoding IETF JSON payloads
## Model files are loaded recursively from the given directories. Disabled if
## no models are specified.
# yang_model_paths = []
## Define additional aliases to map encoding paths to measurement names
# [inputs.gnmi.aliases]
# ifcounters = "openconfig:/interfaces/interface/state/counters"
[[inputs.gnmi.subscription]]
## Name of the measurement that will be emitted
name = "ifcounters"
## Origin and path of the subscription
## See: https://github.com/openconfig/reference/blob/master/rpc/gnmi/gnmi-specification.md#222-paths
##
## origin usually refers to a (YANG) data model implemented by the device
## and path to a specific substructure inside it that should be subscribed
## to (similar to an XPath). YANG models can be found e.g. here:
## https://github.com/YangModels/yang/tree/master/vendor/cisco/xr
origin = "openconfig-interfaces"
path = "/interfaces/interface/state/counters"
## Subscription mode ("target_defined", "sample", "on_change") and interval
subscription_mode = "sample"
sample_interval = "10s"
## Suppress redundant transmissions when measured values are unchanged
# suppress_redundant = false
## If suppression is enabled, send updates at least every X seconds anyway
# heartbeat_interval = "60s"
Microsoft SQL Server
[[outputs.sql]]
## Database driver
## Valid options: mssql (Microsoft SQL Server), mysql (MySQL), pgx (Postgres),
## sqlite (SQLite3), snowflake (snowflake.com), clickhouse (ClickHouse)
driver = "mssql"
## Data source name
## For Microsoft SQL Server, the DSN typically includes the server, port, username, password, and database name.
## Example DSN: "sqlserver://username:password@localhost:1433?database=telegraf"
data_source_name = "sqlserver://username:password@localhost:1433?database=telegraf"
## Timestamp column name
timestamp_column = "timestamp"
## Table creation template
## Available template variables:
## {TABLE} - table name as a quoted identifier
## {TABLELITERAL} - table name as a quoted string literal
## {COLUMNS} - column definitions (list of quoted identifiers and types)
table_template = "CREATE TABLE {TABLE} ({COLUMNS})"
## Table existence check template
## Available template variables:
## {TABLE} - table name as a quoted identifier
table_exists_template = "SELECT 1 FROM {TABLE} LIMIT 1"
## Initialization SQL (optional)
init_sql = ""
## Maximum amount of time a connection may be idle. "0s" means connections are never closed due to idle time.
connection_max_idle_time = "0s"
## Maximum amount of time a connection may be reused. "0s" means connections are never closed due to age.
connection_max_lifetime = "0s"
## Maximum number of connections in the idle connection pool. 0 means unlimited.
connection_max_idle = 2
## Maximum number of open connections to the database. 0 means unlimited.
connection_max_open = 0
## Metric type to SQL type conversion
## You can customize the mapping if needed.
#[outputs.sql.convert]
# integer = "INT"
# real = "DOUBLE"
# text = "TEXT"
# timestamp = "TIMESTAMP"
# defaultvalue = "TEXT"
# unsigned = "UNSIGNED"
# bool = "BOOL"
输入和输出集成示例
gNMI
-
监控 Cisco 设备:使用 gNMI 插件从 Cisco IOS XR、NX-OS 或 IOS XE 设备收集遥测数据以进行性能监控。
-
实时网络洞察:借助 gNMI 插件,网络管理员可以深入了解实时指标,例如接口统计信息和 CPU 使用率。
-
安全数据收集:配置具有 TLS 设置的 gNMI 插件,以确保在从设备收集敏感遥测数据时进行安全通信。
-
灵活的数据处理:使用订阅选项自定义您要根据特定需求或要求收集的遥测数据。
-
错误处理:该插件包含故障排除选项,用于处理常见问题,例如缺少指标名称或 TLS 握手失败。
Microsoft SQL Server
-
企业应用程序监控:利用该插件捕获从 SQL Server 上运行的企业应用程序的详细性能指标。 此设置允许 IT 团队分析系统性能、跟踪事务时间并识别跨复杂多层环境的瓶颈。
-
动态基础设施审计:部署该插件以在 SQL Server 中创建基础设施更改和性能指标的动态审计日志。 此用例非常适合需要实时监控和系统性能历史分析以进行合规性和优化的组织。
-
自动化性能基准测试:使用该插件持续记录和分析 SQL Server 数据库的性能指标。 这实现了自动化基准测试,将历史数据与当前性能进行比较,从而帮助快速识别服务中的异常或降级。
-
集成 DevOps 仪表板:将该插件与 DevOps 监控工具集成,以将来自 SQL Server 的实时指标馈送到集中式仪表板中。 这提供了应用程序运行状况的整体视图,使团队能够将 SQL Server 性能与应用程序级事件相关联,从而更快地进行故障排除和主动维护。
反馈
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强大的性能,无限的扩展
收集、组织和处理海量高速数据。当您将任何数据视为时间序列数据时,它都更有价值。 借助 InfluxDB,排名第一的时间序列平台,它旨在与 Telegraf 一起扩展。
查看入门方法
