3.5 KiB
3.5 KiB
title, description, tags
| title | description | tags |
|---|---|---|
| Primary Key Design | Primary key patterns | mysql, primary-keys, auto-increment, uuid, innodb |
Primary Keys
InnoDB stores rows in primary key order (clustered index). This means:
- Sequential keys = optimal inserts: new rows append, minimizing page splits and fragmentation.
- Random keys = fragmentation: random inserts cause page splits to maintain PK order, wasting space and slowing inserts.
- Secondary index lookups: secondary indexes store the PK value and use it to fetch the full row from the clustered index.
INT vs BIGINT for Primary Keys
- INT UNSIGNED: 4 bytes, max ~4.3B rows.
- BIGINT UNSIGNED: 8 bytes, max ~18.4 quintillion rows.
Guideline: default to BIGINT UNSIGNED unless you're certain the table will never approach the INT limit. The extra 4 bytes is usually cheaper than the risk of exhausting INT.
Avoid Random UUID as Clustered PK
- UUID PK stored as
BINARY(16): 16 bytes (vs 8 for BIGINT). Random inserts cause page splits, and every secondary index entry carries the PK. - UUID stored as
CHAR(36)/VARCHAR(36): 36 bytes (+ overhead) and is generally worse for storage and index size. - If external identifiers are required, store UUID as
BINARY(16)in a secondary unique column:
CREATE TABLE users (
id BIGINT UNSIGNED NOT NULL AUTO_INCREMENT PRIMARY KEY,
public_id BINARY(16) NOT NULL,
UNIQUE KEY idx_public_id (public_id)
);
-- UUID_TO_BIN(uuid, 1) reorders UUIDv1 bytes to be roughly time-sorted (reduces fragmentation)
-- MySQL's UUID() returns UUIDv4 (random). For time-ordered IDs, use app-generated UUIDv7/ULID/Snowflake.
INSERT INTO users (public_id) VALUES (UUID_TO_BIN(?, 1)); -- app provides UUID string
If UUIDs are required, prefer time-ordered variants such as UUIDv7 (app-generated) to reduce index fragmentation.
Secondary Indexes Include the Primary Key
InnoDB secondary indexes store the primary key value with each index entry. Implications:
- Larger secondary indexes: a secondary index entry includes (indexed columns + PK bytes).
- Covering reads:
SELECT id FROM users WHERE email = ?can often be satisfied fromINDEX(email)becauseid(PK) is already present in the index entry. - UUID penalty: a
BINARY(16)PK makes every secondary index entry 8 bytes larger than a BIGINT PK.
Auto-Increment Considerations
- Hot spot: inserts target the end of the clustered index (usually fine; can bottleneck at extreme insert rates).
- Gaps are normal: rollbacks or failed inserts can leave gaps.
- Locking: auto-increment allocation can introduce contention under very high concurrency.
Alternative Ordered IDs (Snowflake / ULID / UUIDv7)
If you need globally unique IDs generated outside the database:
- Snowflake-style: 64-bit integers (fits in BIGINT), time-ordered, compact.
- ULID / UUIDv7: 128-bit (store as
BINARY(16)), time-ordered, better insert locality than random UUIDv4.
Recommendation: prefer BIGINT AUTO_INCREMENT unless you need distributed ID generation or externally meaningful identifiers.
Replication Considerations
- Random-key insert patterns (UUIDv4) can amplify page splits and I/O on replicas too, increasing lag.
- Time-ordered IDs reduce fragmentation and tend to replicate more smoothly under heavy insert workloads.
Composite Primary Keys
Use for join/many-to-many tables. Most-queried column first:
CREATE TABLE user_roles (
user_id BIGINT UNSIGNED NOT NULL,
role_id BIGINT UNSIGNED NOT NULL,
PRIMARY KEY (user_id, role_id)
);