翻译自
https://microservices.io/patterns/data/database-per-service.html
写在前面
公司采用微服务模式重构了产品线,但是在微服务化过程中遇到一些问题,例如:
1.分布式事务;
2.基础数据共享;
3.跨库关联查询;
4.单个服务部署集群遇到的问题,像缓存一致性、定时任务单点处理、请求负载均衡、topic消息消费等;
针对基础数据共享,笔者开发了一个数据同步jar包已经较好的解决了该问题,但是对于分布式事务和跨服务数据关联依然存在很多疑惑。在查阅资料过程中,发现了https://microservices.io/
该博客,因此对其中部分内容进行摘录和解读。
Pattern: Database per service
Context
Let’s imagine you are developing an online store application using the Microservice architecture pattern. Most services need to persist data in some kind of database. For example, the Order Service
stores information about orders and the Customer Service
stores information about customers.
Problem
What’s the database architecture in a microservices application?
Forces
Services must be loosely coupled so that they can be developed, deployed and scaled independently
Some business transactions must enforce invariants that span multiple services. For example, the
Place Order
use case must verify that a new Order will not exceed the customer’s credit limit. Other business transactions, must update data owned by multiple services.Some business transactions need to query data that is owned by multiple services. For example, the
View Available Credit
use must query the Customer to find thecreditLimit
and Orders to calculate the total amount of the open orders.Some queries must join data that is owned by multiple services. For example, finding customers in a particular region and their recent orders requires a join between customers and orders.
Databases must sometimes be replicated and sharded in order to scale. See the Scale Cube.
Different services have different data storage requirements. For some services, a relational database is the best choice. Other services might need a NoSQL database such as MongoDB, which is good at storing complex, unstructured data, or Neo4J, which is designed to efficiently store and query graph data.
Solution
Keep each microservice’s persistent data private to that service and accessible only via its API. A service’s transactions only involve its database.
The following diagram shows the structure of this pattern.
The service’s database is effectively part of the implementation of that service. It cannot be accessed directly by other services.
There are a few different ways to keep a service’s persistent data private. You do not need to provision a database server for each service. For example, if you are using a relational database then the options are:
- Private-tables-per-service – each service owns a set of tables that must only be accessed by that service
- Schema-per-service – each service has a database schema that’s private to that service
- Database-server-per-service – each service has it’s own database server.
Private-tables-per-service and schema-per-service have the lowest overhead. Using a schema per service is appealing since it makes ownership clearer. Some high throughput services might need their own database server.
It is a good idea to create barriers that enforce this modularity. You could, for example, assign a different database user id to each service and use a database access control mechanism such as grants. Without some kind of barrier to enforce encapsulation, developers will always be tempted to bypass a service’s API and access it’s data directly.
Example
The FTGO application is an example of an application that uses this approach. Each service has database credentials that only grant it access its own (logical) database on a shared MySQL server. For more information, see this blog post.
Resulting context
每个服务使用独立的数据持久化有以下优点:
1.松耦合,改变一个服务的数据库不影响其他服务
2.每个服务可以使用最合适的数据库类型,例如es,mongo等
Using a database per service has the following benefits:
Helps ensure that the services are loosely coupled. Changes to one service’s database does not impact any other services.
Each service can use the type of database that is best suited to its needs. For example, a service that does text searches could use ElasticSearch. A service that manipulates a social graph could use Neo4j.
也会有下面的缺点
1.分布式事务
2.跨库联查(join)
3.管理多种不同数据库是一个麻烦事
Using a database per service has the following drawbacks:
Implementing business transactions that span multiple services is not straightforward. Distributed transactions are best avoided because of the CAP theorem. Moreover, many modern (NoSQL) databases don’t support them.
Implementing queries that join data that is now in multiple databases is challenging.
Complexity of managing multiple SQL and NoSQL databases
There are various patterns/solutions for implementing transactions and queries that span services:
Implementing transactions that span services - use the Saga pattern.
-
Implementing queries that span services:
API Composition - the application performs the join rather than the database. For example, a service (or the API gateway) could retrieve a customer and their orders by first retrieving the customer from the customer service and then querying the order service to return the customer’s most recent orders.
Command Query Responsibility Segregation (CQRS) - maintain one or more materialized views that contain data from multiple services. The views are kept by services that subscribe to events that each services publishes when it updates its data. For example, the online store could implement a query that finds customers in a particular region and their recent orders by maintaining a view that joins customers and orders. The view is updated by a service that subscribes to customer and order events.
Related patterns
- Microservice architecture pattern creates the need for this pattern
- Saga pattern is a useful way to implement eventually consistent transactions
- The API Composition and Command Query Responsibility Segregation (CQRS) pattern are useful ways to implement queries
- The Shared Database anti-pattern describes the problems that result from microservices sharing a database