EDIT: More explanation of synchronization using bi-directional triggers; updates for syntax, language and clarity.
I have faced similar problems on a data model upgrade on a large web application I worked on for 7 years, so I feel your pain. From this experience, I would propose the something a bit different - but hopefully one that will be a lot easier to implement. But first, an observation:
Value to the organisation is the data - data will long outlive all your current applications. The business will constantly invent new ways of getting value out of the data it has captured which will engender new reports, applications and ways of doing business.
So getting the new data structure right should be your most important goal. Don't trade getting the structure right against against other short term development goals, especially:
- Operational goals such as rolling out a new service
- Report performance (use materialized views, triggers or batch jobs instead)
This structure will change over time so your architecture must allow for frequent additions and infrequent normalizations to it. This means that your data structure and any shared APIs to it (including RESTful services) must be properly versioned.
Why RESTful web services?
You mention that your will "Move all functionality to a RESTful service so no application has direct database access". I need to ask a very important question with respect to the legacy apps: Why is this important and what value has it brought?
I ask because:
- You lose ACID transactions (each call is a single transaction unless you implement some horrifically complicated WS-* standards)
- Performance degrades: Direct database connections will be faster (no web server work and translations to do) and have less latency (typically 1ms rather than 50-100ms) which will visibly reduce responsiveness in applications written for direct DB connections
- The database structure is not abstracted from the RESTful service, because you acknowledge that with the database normalization you have to rewrite the web services and rewrite the applications calling them.
And the other cross-cutting concerns are unchanged:
- Manageability: Direct database connections can be monitored and managed with many generic tools here
- Security: direct connections are more secure than web services that your developers will write,
- Authorization: The database permission model is very advanced and as fine-grained as you could want
- Scaleability: The web service is a (only?) direct-connected database application and so scales only as much as the database
You can migrate the database and keep the legacy applications running by maintaining a legacy RESTful API. But what if we can keep the legacy apps without introducing a 'legacy' RESTful service.
Presumably the majority of the 'legacy' applications use SQL to directly access data tables; you may have a number of database views as well.
One approach to the data migration is that the new database (with the new normalized structure in a new schema) presents the old structure as views to the legacy applications, typically from a different schema.
This is actually quite easy to implement, but solves only reporting and read-only functionality. What about legacy application DML? DML can be solved using
- Updatable views for simple transformations
- Introducing stored procedures where updatable views not possible (eg "CALL insert_emp(?, ?, ?)" rather than "INSERT INTO EMP (col1, col2, col3) VALUES (?, ? ?)".
- Have a 'legacy' table that synchronizes with the new database with triggers and DB links.
Having a legacy-format table with bi-directional synchronization to the new format table(s) using triggers is a brute-force solution and relatively ugly.
You end up with identical data in two different schemas (or databases) and the possibility of data going out-of-sync if the synchronization code has bugs - and then you have the classic issues of the "two master" problem. As such, treat this as a last resort, for example when:
- The fundamental structure has changed (for example the changing the cardinality of a relation), or
- The translation to the legacy format is a complex function (eg if the legacy column is the square of the new-format column value and is set to "4", an updatable view cannot determine if the correct value is +2 or -2).
When such changes are required in your data, there will be some significant change in code and logic somewhere. You could implement in a compatibility layer (advantage: no change to legacy code) or change the legacy app (advantage: data layer is clean). This is a technical decision by the engineering team.
Creating a compatibility database of the legacy structure using the approaches outlined above minimize changes to legacy applications (in some cases, the legacy application continues without any code change at all). This greatly reduces development and testing costs (for which there is no net functional gain to the business), and greatly reduces rollout risk.
It also allows you to concentrate on the real value to the organisation:
- The new database structure
- New RESTful web services
- New applications (potentially build using the RESTful web services)
Positive aspect of web services
Please don't read the above as a diatribe against web services, especially RESTful web services. When used for the right reason, such as for enabling web applications or integration between disparate systems, this is a good architectural solution. However, it might not be the best solution for managing your legacy apps during the data migration.