clickhouse-io

clickhouse-io

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ClickHouse数据库模式、查询优化、分析以及面向高性能分析工作负载的数据工程最佳实践。

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更新于 2026/7/14
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clickhouse-io
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ClickHouse数据库模式、查询优化、分析以及面向高性能分析工作负载的数据工程最佳实践。

ClickHouse 分析模式

面向高性能分析和数据工程的 ClickHouse 特定模式。

何时激活

  • 设计 ClickHouse 表结构(MergeTree 引擎选择)
  • 编写分析查询(聚合、窗口函数、连接)
  • 优化查询性能(分区裁剪、投影、物化视图)
  • 批量导入大量数据(批量插入、Kafka 集成)
  • 从 PostgreSQL/MySQL 迁移到 ClickHouse 进行分析
  • 实现实时仪表盘或时间序列分析

概述

ClickHouse 是一个面向在线分析处理(OLAP)的列式数据库管理系统(DBMS)。它针对大数据集上的快速分析查询进行了优化。

关键特性:

  • 列式存储
  • 数据压缩
  • 并行查询执行
  • 分布式查询
  • 实时分析

表设计模式

MergeTree 引擎(最常用)

CREATE TABLE markets_analytics (
    date Date,
    market_id String,
    market_name String,
    volume UInt64,
    trades UInt32,
    unique_traders UInt32,
    avg_trade_size Float64,
    created_at DateTime
) ENGINE = MergeTree()
PARTITION BY toYYYYMM(date)
ORDER BY (date, market_id)
SETTINGS index_granularity = 8192;

ReplacingMergeTree(去重)

-- 适用于可能存在重复数据的情况(例如来自多个源)
CREATE TABLE user_events (
    event_id String,
    user_id String,
    event_type String,
    timestamp DateTime,
    properties String
) ENGINE = ReplacingMergeTree()
PARTITION BY toYYYYMM(timestamp)
ORDER BY (user_id, event_id, timestamp)
PRIMARY KEY (user_id, event_id);

AggregatingMergeTree(预聚合)

-- 用于维护聚合指标
CREATE TABLE market_stats_hourly (
    hour DateTime,
    market_id String,
    total_volume AggregateFunction(sum, UInt64),
    total_trades AggregateFunction(count, UInt32),
    unique_users AggregateFunction(uniq, String)
) ENGINE = AggregatingMergeTree()
PARTITION BY toYYYYMM(hour)
ORDER BY (hour, market_id);

-- 查询聚合数据
SELECT
    hour,
    market_id,
    sumMerge(total_volume) AS volume,
    countMerge(total_trades) AS trades,
    uniqMerge(unique_users) AS users
FROM market_stats_hourly
WHERE hour >= toStartOfHour(now() - INTERVAL 24 HOUR)
GROUP BY hour, market_id
ORDER BY hour DESC;

查询优化模式

高效过滤

-- 通过:良好:优先使用索引列
SELECT *
FROM markets_analytics
WHERE date >= '2025-01-01'
  AND market_id = 'market-123'
  AND volume > 1000
ORDER BY date DESC
LIMIT 100;

-- 失败:糟糕:先过滤非索引列
SELECT *
FROM markets_analytics
WHERE volume > 1000
  AND market_name LIKE '%election%'
  AND date >= '2025-01-01';

聚合

-- 通过:良好:使用 ClickHouse 特定的聚合函数
SELECT
    toStartOfDay(created_at) AS day,
    market_id,
    sum(volume) AS total_volume,
    count() AS total_trades,
    uniq(trader_id) AS unique_traders,
    avg(trade_size) AS avg_size
FROM trades
WHERE created_at >= today() - INTERVAL 7 DAY
GROUP BY day, market_id
ORDER BY day DESC, total_volume DESC;

-- 通过:使用 quantile 计算百分位数(比 percentile 更高效)
SELECT
    quantile(0.50)(trade_size) AS median,
    quantile(0.95)(trade_size) AS p95,
    quantile(0.99)(trade_size) AS p99
FROM trades
WHERE created_at >= now() - INTERVAL 1 HOUR;

窗口函数

-- 计算累计总和
SELECT
    date,
    market_id,
    volume,
    sum(volume) OVER (
        PARTITION BY market_id
        ORDER BY date
        ROWS BETWEEN UNBOUNDED PRECEDING AND CURRENT ROW
    ) AS cumulative_volume
FROM markets_analytics
WHERE date >= today() - INTERVAL 30 DAY
ORDER BY market_id, date;

数据插入模式

批量插入(推荐)

import { createClient } from '@clickhouse/client'

const clickhouse = createClient({
  url: process.env.CLICKHOUSE_URL ?? 'http://localhost:8123',
  username: process.env.CLICKHOUSE_USER,
  password: process.env.CLICKHOUSE_PASSWORD
})

// 通过:批量插入(高效)
async function bulkInsertTrades(trades: Trade[]) {
  await clickhouse.insert({
    table: 'trades',
    values: trades.map(trade => ({
      id: trade.id,
      market_id: trade.market_id,
      user_id: trade.user_id,
      amount: trade.amount,
      timestamp: trade.timestamp.toISOString()
    })),
    format: 'JSONEachRow'
  })
}

// 失败:单条插入(慢)
async function insertTrade(trade: Trade) {
  // 不要在循环中这样做!
  await clickhouse.insert({
    table: 'trades',
    values: [{
      id: trade.id,
      market_id: trade.market_id,
      user_id: trade.user_id,
      amount: trade.amount,
      timestamp: trade.timestamp.toISOString()
    }],
    format: 'JSONEachRow'
  })
}

流式插入

// 用于持续数据摄入
import { Readable } from 'node:stream'

async function streamInserts(dataSource: AsyncIterable<Record<string, unknown>>) {
  await clickhouse.insert({
    table: 'trades',
    values: Readable.from(dataSource, { objectMode: true }),
    format: 'JSONEachRow'
  })
}

物化视图

实时聚合

-- 创建用于小时统计的物化视图
CREATE MATERIALIZED VIEW market_stats_hourly_mv
TO market_stats_hourly
AS SELECT
    toStartOfHour(timestamp) AS hour,
    market_id,
    sumState(amount) AS total_volume,
    countState() AS total_trades,
    uniqState(user_id) AS unique_users
FROM trades
GROUP BY hour, market_id;

-- 查询物化视图
SELECT
    hour,
    market_id,
    sumMerge(total_volume) AS volume,
    countMerge(total_trades) AS trades,
    uniqMerge(unique_users) AS users
FROM market_stats_hourly
WHERE hour >= now() - INTERVAL 24 HOUR
GROUP BY hour, market_id;

性能监控

查询性能

-- 检查慢查询
SELECT
    query_id,
    user,
    query,
    query_duration_ms,
    read_rows,
    read_bytes,
    memory_usage
FROM system.query_log
WHERE type = 'QueryFinish'
  AND query_duration_ms > 1000
  AND event_time >= now() - INTERVAL 1 HOUR
ORDER BY query_duration_ms DESC
LIMIT 10;

表统计信息

-- 检查表大小
SELECT
    database,
    table,
    formatReadableSize(sum(bytes)) AS size,
    sum(rows) AS rows,
    max(modification_time) AS latest_modification
FROM system.parts
WHERE active
GROUP BY database, table
ORDER BY sum(bytes) DESC;

常用分析查询

时间序列分析

-- 每日活跃用户
SELECT
    toDate(timestamp) AS date,
    uniq(user_id) AS daily_active_users
FROM events
WHERE timestamp >= today() - INTERVAL 30 DAY
GROUP BY date
ORDER BY date;

-- 留存分析
SELECT
    signup_date,
    countIf(days_since_signup = 0) AS day_0,
    countIf(days_since_signup = 1) AS day_1,
    countIf(days_since_signup = 7) AS day_7,
    countIf(days_since_signup = 30) AS day_30
FROM (
    SELECT
        user_id,
        min(toDate(timestamp)) AS signup_date,
        toDate(timestamp) AS activity_date,
        dateDiff('day', signup_date, activity_date) AS days_since_signup
    FROM events
    GROUP BY user_id, activity_date
)
GROUP BY signup_date
ORDER BY signup_date DESC;

漏斗分析

-- 转化漏斗
SELECT
    countIf(step = 'viewed_market') AS viewed,
    countIf(step = 'clicked_trade') AS clicked,
    countIf(step = 'completed_trade') AS completed,
    round(clicked / viewed * 100, 2) AS view_to_click_rate,
    round(completed / clicked * 100, 2) AS click_to_completion_rate
FROM (
    SELECT
        user_id,
        session_id,
        event_type AS step
    FROM events
    WHERE event_date = today()
)
GROUP BY session_id;

同期群分析

-- 按注册月份划分的用户同期群
SELECT
    toStartOfMonth(signup_date) AS cohort,
    toStartOfMonth(activity_date) AS month,
    dateDiff('month', cohort, month) AS months_since_signup,
    count(DISTINCT user_id) AS active_users
FROM (
    SELECT
        user_id,
        min(toDate(timestamp)) OVER (PARTITION BY user_id) AS signup_date,
        toDate(timestamp) AS activity_date
    FROM events
)
GROUP BY cohort, month, months_since_signup
ORDER BY cohort, months_since_signup;

数据管道模式

ETL 模式

// 提取、转换、加载
async function etlPipeline() {
  // 1. 从源提取
  const rawData = await extractFromPostgres()

  // 2. 转换
  const transformed = rawData.map(row => ({
    date: new Date(row.created_at).toISOString().split('T')[0],
    market_id: row.market_slug,
    volume: parseFloat(row.total_volume),
    trades: parseInt(row.trade_count)
  }))

  // 3. 加载到 ClickHouse
  await bulkInsertToClickHouse(transformed)
}

// 定期运行
setInterval(etlPipeline, 60 * 60 * 1000)  // 每小时

变更数据捕获(CDC)

// 监听 PostgreSQL 变更并同步到 ClickHouse
import { Client } from 'pg'

const pgClient = new Client({ connectionString: process.env.DATABASE_URL })

pgClient.query('LISTEN market_updates')

pgClient.on('notification', async (msg) => {
  const update = JSON.parse(msg.payload)

  await clickhouse.insert({
    table: 'market_updates',
    values: [
      {
        market_id: update.id,
        event_type: update.operation,  // INSERT, UPDATE, DELETE
        timestamp: new Date(),
        data: JSON.stringify(update.new_data)
      }
    ],
    format: 'JSONEachRow'
  })
})

最佳实践

1. 分区策略

  • 按时间分区(通常按月或天)
  • 避免过多分区(影响性能)
  • 使用 DATE 类型作为分区键

2. 排序键

  • 将最常过滤的列放在前面
  • 考虑基数(高基数在前)
  • 排序影响压缩

3. 数据类型

  • 使用最小的合适类型(UInt32 vs UInt64)
  • 对重复字符串使用 LowCardinality
  • 对分类数据使用 Enum

4. 避免

  • SELECT *(指定列)
  • FINAL(改为在查询前合并数据)
  • 过多 JOIN(为分析进行反规范化)
  • 频繁的小批量插入(改为批量插入)

5. 监控

  • 跟踪查询性能
  • 监控磁盘使用情况
  • 检查合并操作
  • 查看慢查询日志

记住:ClickHouse 擅长分析型工作负载。根据查询模式设计表,批量插入,并利用物化视图进行实时聚合。