First, in my experience, people don't write long one-line expressions in Python… Of course you can, but PEP 8 discourages it, and the tutorial, stdlib, and other sample code you usually learn from doesn't look like that.
However, people do write very complex expressions. In particular, they use things like comprehensions and iterators.
Anyway, either way, it's somewhat ambiguous what the subexpressions of such a thing are, so it's not clear what it should meant to step into them.
Let's take a trivial example:
x = [i*2 for i in range(3)]
range(3) is a subexpression. But what else? Is
i*2 a subexpression? Or three of them?
Under the covers, what this actually looks like is:
x = _hidden_func(range(3))
And that hidden function (which is actually named something like
_hidden_func) was built directly out of bytecode at compile time, and doesn't map to any actual valid Python code. It's roughly like this:
result = 
iterator = iter(iterable)
i = next(iterator)
… but it uses fast list-building and
StopIteration-handling bytecodes that don't map to anything you could actually write.
So, in order to see the
i*2 at all, you'd need to step into a function that has no source code, and can't even be decompiled into source code on the fly.
pdb can already do this… but it can't show you anything interesting.
There are obviously a variety of things you could do with this code. And you could pick one of those things and write custom code that does it. This visualizer shows one possibility.
The same visualizer treats a long but simple expression, like
x = 2 * i**2 + 3 * i + 4, as a single step, but you could obviously handle that by, e.g., stepping through the bytecodes and decompiling each "interesting" bytecode.
But again, you'd have to decide what counts as "interesting", and write the appropriate code.
i**2 is probably interested, but what about
i? Do you care whether it's doing a local, closure, or global lookup to get it, or what that lookup finds, or do you just want to skip it?