数据库审计
- 作者仓库星标 36,312
- 作者更新于 实时读取
- 作者仓库 agents
- 领域
- 设计与多媒体
- 兼容 Agent
-
- Claude Code
- Cursor
- Cline
- Codex
- Windsurf
- Gemini CLI
- +20
- 信任分
- 88 / 100 · 社区维护
- 作者 / 版本 / 许可
- @wshobson · 未声明 license
- Token 消耗评级
- 低消耗
- 接入复杂程度
- 需简单配置
- 是否需要外部 API Key
- 不需要
- 兼容的系统
- 未声明(默认跨平台)
- 底层运行要求
- 无特殊要求
- 文件与系统权限
-
- 只读
- 允许写入 / 修改
- Shell 执行
- 网络行为
- 允许外网请求
- 安装命令数
- 26 条
档案由构建时根据 SKILL.md 与安装命令自动衍生,可能与作者实际意图存在差异。
需要注意: 未限定 allowed-tools,默认拥有全部工具权限。
---
name: sql-optimization-patterns
description: Master SQL query optimization, indexing strategies, and EXPLAIN analysis to dramatically improve…
category: 设计与多媒体
runtime: 无特殊运行时
---
# sql-optimization-patterns 输出预览
## PART A: 任务判断
- 适用问题:视觉内容、演示材料、信息图或设计交付。
- 输入要求:目标材料、限制条件、期望输出和验收方式。
- 证据边界:围绕“When to Use This Skill / Core Concepts / 1. Query Execution Plans (EXPLAIN)”读取原文规则,不把推断写成作者承诺。
## PART B: 执行结果
- **01** 任务判断:确认你的需求是否属于视觉内容、演示材料、信息图或设计交付,并标出输入、限制和预期结果。
- **02** 执行计划:优先按“When to Use This Skill / Core Concepts / 1. Query Execution Plans (EXPLAIN)”拆成步骤,说明每一步会读取什么、修改什么、产出什么。
- **03** 交付结果:给出可复制的命令、文件改动、检查清单或内容草稿,并说明如何继续迭代。
- **04** 风险边界:结合 读取文件、写入/修改文件、执行终端命令、会按任务需要访问外部网络、通常不需要额外 API Key 给出执行前确认项。
## Running Rules
- 读取文件、写入/修改文件、执行终端命令;会按任务需要访问外部网络;通常不需要额外 API Key。
- 先小样例验证,再放大到真实任务。
- 交付时同时给结果、检查口径和下一步迭代建议。 原文没有稳定的斜杠命令要求。安装验证后通常全局生效,直接在对话里点名这个 Skill 并描述任务即可。
告诉 Agent 目标文件或材料、期望结果、不可改范围、是否允许联网或执行命令。本 Skill 的权限画像是:读取文件、写入/修改文件、执行终端命令。
先用一个小任务确认它会围绕“When to Use This Skill / Core Concepts / 1. Query Execution Plans (EXPLAIN)”工作;涉及文件或命令时,先看 diff、日志、预览或测试结果。
检查最终产物是否包含明确结果、必要证据和下一步动作;如果输出泛泛而谈,就补充输入、边界和验收标准后重跑。
---
name: sql-optimization-patterns
description: Master SQL query optimization, indexing strategies, and EXPLAIN analysis to dramatically improve…
category: 设计与多媒体
source: wshobson/agents
---
# sql-optimization-patterns
## 什么时候使用
- 把设计与视觉方向的常用动作沉淀成 Agent 可调用的技能 适合处理界面、视觉、封面、信息图或演示材料交付,核心价值是把输入、判断、执行、验证和交付边界固定下来,避免 Agent 泛泛回答。 把任务拆成可执行、可检查、可继续迭代的步骤…
- 面向视觉内容、演示材料、信息图或设计交付,优先处理能明确输入、步骤和验收标准的工作。
## 需要提供什么
- 目标材料、目录范围、期望结果和不可改动内容。
- 是否允许联网、执行命令、读写文件或调用外部服务。
## 执行规则
- 围绕「When to Use This Skill / Core Concepts / 1. Query Execution Plans (EXPLAIN)」组织步骤,不把推断写成作者事实。
- 读取文件、写入/修改文件、执行终端命令;会按任务需要访问外部网络;通常不需要额外 API Key。
- 先跑小样例,确认结果可检查后再扩大任务范围。
## 输出要求
- 给出最终产物、关键证据、验证方式和下一步动作。
- 信息不足时标记 unknown,不编造命令、平台或依赖。 作者原文负责流程事实;仓库文件负责来源和命令;流狐只补充适用场景、限制和质量判断。
skill "sql-optimization-patterns" {
输入层 -> 用户目标 + 目标文件 + 禁止范围 + 验收标准
上下文层 -> When to Use This Skill / Core Concepts / 1. Query Execution Plans (EXPLAIN)
规则层 -> SKILL.md 触发条件 / 执行顺序 / 输出格式
运行层 -> 无特殊运行时 | 读取文件、写入/修改文件、执行终端命令 | 会按任务需要访问外部网络
安全层 -> 通常不需要额外 API Key + 小任务验证 + diff / 日志复核
输出层 -> 可复制结果 + 检查清单 + 下一步迭代
} SQL Optimization Patterns
Transform slow database queries into lightning-fast operations through systematic optimization, proper indexing, and query plan analysis.
When to Use This Skill
- Debugging slow-running queries
- Designing performant database schemas
- Optimizing application response times
- Reducing database load and costs
- Improving scalability for growing datasets
- Analyzing EXPLAIN query plans
- Implementing efficient indexes
- Resolving N+1 query problems
Core Concepts
1. Query Execution Plans (EXPLAIN)
Understanding EXPLAIN output is fundamental to optimization.
PostgreSQL EXPLAIN:
-- Basic explain
EXPLAIN SELECT * FROM users WHERE email = 'user@example.com';
-- With actual execution stats
EXPLAIN ANALYZE
SELECT * FROM users WHERE email = 'user@example.com';
-- Verbose output with more details
EXPLAIN (ANALYZE, BUFFERS, VERBOSE)
SELECT u.*, o.order_total
FROM users u
JOIN orders o ON u.id = o.user_id
WHERE u.created_at > NOW() - INTERVAL '30 days';
Key Metrics to Watch:
- Seq Scan: Full table scan (usually slow for large tables)
- Index Scan: Using index (good)
- Index Only Scan: Using index without touching table (best)
- Nested Loop: Join method (okay for small datasets)
- Hash Join: Join method (good for larger datasets)
- Merge Join: Join method (good for sorted data)
- Cost: Estimated query cost (lower is better)
- Rows: Estimated rows returned
- Actual Time: Real execution time
2. Index Strategies
Indexes are the most powerful optimization tool.
Index Types:
- B-Tree: Default, good for equality and range queries
- Hash: Only for equality (=) comparisons
- GIN: Full-text search, array queries, JSONB
- GiST: Geometric data, full-text search
- BRIN: Block Range INdex for very large tables with correlation
-- Standard B-Tree index
CREATE INDEX idx_users_email ON users(email);
-- Composite index (order matters!)
CREATE INDEX idx_orders_user_status ON orders(user_id, status);
-- Partial index (index subset of rows)
CREATE INDEX idx_active_users ON users(email)
WHERE status = 'active';
-- Expression index
CREATE INDEX idx_users_lower_email ON users(LOWER(email));
-- Covering index (include additional columns)
CREATE INDEX idx_users_email_covering ON users(email)
INCLUDE (name, created_at);
-- Full-text search index
CREATE INDEX idx_posts_search ON posts
USING GIN(to_tsvector('english', title || ' ' || body));
-- JSONB index
CREATE INDEX idx_metadata ON events USING GIN(metadata);
3. Query Optimization Patterns
Avoid SELECT *:
-- Bad: Fetches unnecessary columns
SELECT * FROM users WHERE id = 123;
-- Good: Fetch only what you need
SELECT id, email, name FROM users WHERE id = 123;
Use WHERE Clause Efficiently:
-- Bad: Function prevents index usage
SELECT * FROM users WHERE LOWER(email) = 'user@example.com';
-- Good: Create functional index or use exact match
CREATE INDEX idx_users_email_lower ON users(LOWER(email));
-- Then:
SELECT * FROM users WHERE LOWER(email) = 'user@example.com';
-- Or store normalized data
SELECT * FROM users WHERE email = 'user@example.com';
Optimize JOINs:
-- Bad: Cartesian product then filter
SELECT u.name, o.total
FROM users u, orders o
WHERE u.id = o.user_id AND u.created_at > '2024-01-01';
-- Good: Filter before join
SELECT u.name, o.total
FROM users u
JOIN orders o ON u.id = o.user_id
WHERE u.created_at > '2024-01-01';
-- Better: Filter both tables
SELECT u.name, o.total
FROM (SELECT * FROM users WHERE created_at > '2024-01-01') u
JOIN orders o ON u.id = o.user_id;
Detailed patterns and worked examples
Detailed pattern documentation lives in references/details.md. Read that file when the navigation tier above is insufficient.
Best Practices
- Index Selectively: Too many indexes slow down writes
- Monitor Query Performance: Use slow query logs
- Keep Statistics Updated: Run ANALYZE regularly
- Use Appropriate Data Types: Smaller types = better performance
- Normalize Thoughtfully: Balance normalization vs performance
- Cache Frequently Accessed Data: Use application-level caching
- Connection Pooling: Reuse database connections
- Regular Maintenance: VACUUM, ANALYZE, rebuild indexes
-- Update statistics
ANALYZE users;
ANALYZE VERBOSE orders;
-- Vacuum (PostgreSQL)
VACUUM ANALYZE users;
VACUUM FULL users; -- Reclaim space (locks table)
-- Reindex
REINDEX INDEX idx_users_email;
REINDEX TABLE users;
Common Pitfalls
- Over-Indexing: Each index slows down INSERT/UPDATE/DELETE
- Unused Indexes: Waste space and slow writes
- Missing Indexes: Slow queries, full table scans
- Implicit Type Conversion: Prevents index usage
- OR Conditions: Can't use indexes efficiently
- LIKE with Leading Wildcard:
LIKE '%abc'can't use index - Function in WHERE: Prevents index usage unless functional index exists
Monitoring Queries
-- Find slow queries (PostgreSQL)
SELECT query, calls, total_time, mean_time
FROM pg_stat_statements
ORDER BY mean_time DESC
LIMIT 10;
-- Find missing indexes (PostgreSQL)
SELECT
schemaname,
tablename,
seq_scan,
seq_tup_read,
idx_scan,
seq_tup_read / seq_scan AS avg_seq_tup_read
FROM pg_stat_user_tables
WHERE seq_scan > 0
ORDER BY seq_tup_read DESC
LIMIT 10;
-- Find unused indexes (PostgreSQL)
SELECT
schemaname,
tablename,
indexname,
idx_scan,
idx_tup_read,
idx_tup_fetch
FROM pg_stat_user_indexes
WHERE idx_scan = 0
ORDER BY pg_relation_size(indexrelid) DESC;
先判断是否适合
作者设计意图
作者的方法与取舍
边界和复核