What you want is a Program Transformation system.
Good ones have parsers for the language you care about, build ASTs representing the program for the parsed code, provide you with access to the AST for analaysis and modification, and can regenerate source text from the AST. Your remark about "scanning the fields" is just a kind of traversal of the AST representing the program. For each interesting analysis result you produce, you want to make a change to the AST, perhaps somewhere else, but nonetheless in the AST.
And after all the chagnes are made, you want to regenerate text with comments (as originally entered, or as you have constructed in your new code).
There are several tools that do this specifically for Java.
Jackpot provides a parser, builds ASTs, and lets you code Java procedures to do what you want with the trees. Upside: easy conceptually. Downside: you write a lot more Java code to climb around/hack at trees than you'd expect. Jackpot only works with Java.
Stratego and TXL parse your code, build ASTs, and let you write "surce-to-source" transformations (using the syntax of the target language, e.g., Java in this case) to express patterns and fixes. Additional good news: you can define any programming language you like, as the target language to be processed, and both of these have Java definitions.
But they are weak on analysis: often you need symbol tables, and data flow analysis, to really make analyses and changes you need. And they insist that everything is a rewrite rule, whether that helps you or not; this is a little like insisting you only need a hammer in toolbox; after all, everything can be treated like a nail, right?
Our DMS Software Reengineering Toolkit allows the definition of an abitrary target language (and has many predefined langauges including Java), includes all the source-to-source transformation capabilities of Stratego, TXL, the procedural capability of Jackpot,
and additionally provides symbol tables, control and data flow analysis information. The compiler guys taught us these things were necessary to build strong compilers (= "analysis + optimizations + refinement") and it is true of code generation systems too, for exactly the same reasons. Using this approach you can generate code and optimize it to the extent you have the knowledge to do so. One example, similar to your serialization ideas, is to generate fast XML readers and writers for specified XML DTDs; we've done that with DMS for Java and COBOL.
DMS has been used to read/modify/write many kinds of source files. A nice example that will make the ideas clear can be found in this technical paper, which shows how to modify code to insert instrumentation probes: Branch Coverage Made Easy.
A simpler, but more complete example of defining an arbitrary lanauges and transformations to apply to it can be found at How to transform Algebra using the same ideas.