Hopefully I can help shed some light on why bare names work this way here.
First, as others have already noted, if you need to match values as part of your patterns, you can do so by:
- Matching supported literals, like numbers, strings, booleans, and
- Matching qualified (dotted) names
- Using additional tests in guards (which are separated from patterns by
I fear that we (the PEP authors) probably made a small error by including this toy snippet in an early tutorial... it's since gone a bit viral. Our goal was to lead with the simplest possible example of pattern matching, but we instead seem to have also created a confusing first impression for many (especially when repeated without context).
The most overlooked word in the title of these PEPs is "structural". If you're not matching the structure of the subject, structural pattern matching probably isn't the right tool for the job.
The design of this feature was driven by destructuring (like iterable unpacking on the LHS of assignments, but generalized for all objects), which is why we made it very easy to perform the core functionality of extracting out parts of an object and binding them to names. We also decided that it would also be useful to allow programmers to match on values, so we added those (with the condition that when the values are named, they must be qualified with a dot, in order to distinguish them from the more common extractions).
Python's pattern matching was never really designed with the intent of powering C-style switch statements like this; that's been proposed for Python (and rejected) twice before, so we chose to go in a different direction. Besides, there is already one obvious way to switch on a single value, which is simpler, shorter, and works on every version of Python: a good-ol'
SUCCESS = 200
NOT_FOUND = 404
if retcode == SUCCESS:
elif retcode == NOT_FOUND:
(If you're really concerned about performance or need an expression, dispatching from a dictionary is also a fine alternative.)