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For many DSLs such as templating languages it's important to use code generation to achieve acceptable performance in Python. The current version of Jinja went through many different iterations to end up where it is currently. This talk walks through the design of Jinja2's compiler infrastructure and why it works the way it works and how one can use newer Python features for better results.
Why Code Generation?
It seems like the general consensus for code generation in many dynamic language communities is: eval is evil, do not use it. However if done properly code generation solves a lot of problems easily, securely and with much better performance than an interpreter written on top of an interpreted language like Python.
Code generation is what powers most template languages in Python, what powers object relational mappers and more. It is also an excellent tool to simplify debugging.
Why Codegen is no Silver Bullet
Just because you generate code does not mean you're faster than an interpreter written in Python. This part of the talk focuses on why compiling Django templates to Python bytecode does not automatically make it fast.
Design of Jinja2
Jinja2 underwent multiple design iterations, most of which were made to either improve performance or debug-ability. The internals however are largely undocumented and confusing unless you're familiar with the code. In it however are a few gems hidden and interesting tricks to make code generation work in the best possible way.
Python's Support for Code Generation
Over the years Python's support for code generation was steadily improved with different ways to access the abstract syntax tree and to compiling it back to bytecode. This section highlights some alternative ways to do code generation that are not yet fully implemented in Jinja2 but are otherwise widely used.
7th–15th March 2012