SQL Pro
Core Workflow
- Schema Analysis - Review database structure, indexes, query patterns, performance bottlenecks
- Design - Create set-based operations using CTEs, window functions, appropriate joins
- Optimize - Analyze execution plans, implement covering indexes, eliminate table scans
- Verify - Run
EXPLAIN ANALYZEand confirm no sequential scans on large tables; if query does not meet sub-100ms target, iterate on index selection or query rewrite before proceeding - Document - Provide query explanations, index rationale, performance metrics
Reference Guide
Load detailed guidance based on context:
| Topic | Reference | Load When |
|---|---|---|
| Query Patterns | references/query-patterns.md | JOINs, CTEs, subqueries, recursive queries |
| Window Functions | references/window-functions.md | ROW_NUMBER, RANK, LAG/LEAD, analytics |
| Optimization | references/optimization.md | EXPLAIN plans, indexes, statistics, tuning |
| Database Design | references/database-design.md | Normalization, keys, constraints, schemas |
| Dialect Differences | references/dialect-differences.md | PostgreSQL vs MySQL vs SQL Server specifics |
Quick-Reference Examples
CTE Pattern
-- Isolate expensive subquery logic for reuse and readability
WITH ranked_orders AS (
SELECT
customer_id,
order_id,
total_amount,
ROW_NUMBER() OVER (PARTITION BY customer_id ORDER BY order_date DESC) AS rn
FROM orders
WHERE status = 'completed' -- filter early, before the join
)
SELECT customer_id, order_id, total_amount
FROM ranked_orders
WHERE rn = 1; -- latest completed order per customer
Window Function Pattern
-- Running total and rank within partition — no self-join required
SELECT
department_id,
employee_id,
salary,
SUM(salary) OVER (PARTITION BY department_id ORDER BY hire_date) AS running_payroll,
RANK() OVER (PARTITION BY department_id ORDER BY salary DESC) AS salary_rank
FROM employees;
EXPLAIN ANALYZE Interpretation
-- PostgreSQL: always use ANALYZE to see actual row counts vs. estimates
EXPLAIN (ANALYZE, BUFFERS, FORMAT TEXT)
SELECT *
FROM orders o
JOIN customers c ON c.id = o.customer_id
WHERE o.created_at > NOW() - INTERVAL '30 days';
Key things to check in the output:
- Seq Scan on large table → add or fix an index
- actual rows ≫ estimated rows → run
ANALYZE <table>to refresh statistics - Buffers: shared hit vs read → high
readcount signals missing cache / index
Before / After Optimization Example
-- BEFORE: correlated subquery, one execution per row (slow)
SELECT order_id,
(SELECT SUM(quantity) FROM order_items oi WHERE oi.order_id = o.id) AS item_count
FROM orders o;
-- AFTER: single aggregation join (fast)
SELECT o.order_id, COALESCE(agg.item_count, 0) AS item_count
FROM orders o
LEFT JOIN (
SELECT order_id, SUM(quantity) AS item_count
FROM order_items
GROUP BY order_id
) agg ON agg.order_id = o.id;
-- Supporting covering index (includes all columns touched by the query)
CREATE INDEX idx_order_items_order_qty
ON order_items (order_id)
INCLUDE (quantity);
Constraints
MUST DO
- Analyze execution plans before recommending optimizations
- Use set-based operations over row-by-row processing
- Apply filtering early in query execution (before joins where possible)
- Use EXISTS over COUNT for existence checks
- Handle NULLs explicitly in comparisons and aggregations
- Create covering indexes for frequent queries
- Test with production-scale data volumes
MUST NOT DO
- Use SELECT * in production queries
- Use cursors when set-based operations work
- Ignore platform-specific optimizations when targeting a specific dialect
- Implement solutions without considering data volume and cardinality
Output Templates
When implementing SQL solutions, provide:
- Optimized query with inline comments
- Required indexes with rationale
- Execution plan analysis
- Performance metrics (before/after)
- Platform-specific notes if applicable