The difference is, that proving something about an abstraction doesn't prove, that you made no mistakes when translating that abstraction into the actual code running, and therefore you have not proven anything of value about the actually running code.
If the abstraction maintains the properties you care about, PROVABLY, there is no problem. As is the case in this case. Again, the code you see in Isabelle is already an abstraction, it is not "running".
> If the abstraction maintains the properties you care about, PROVABLY, there is no problem.
This approach doesn't do that. The translation from the actual executing code to the representation used for runtime analysis is done entirely informally and not checked at all by Isabelle.
It explains the underlying runtime model they assume, and derives abstractions for the runtime t based on that, which are provably correct up to O(t) under the assumptions.
That does not help you much if you want to know how many seconds this will run. Instead, it tells you the asymptotic runtime complexity of the various algorithms, which is all you can really expect for general functional programs without a concrete machine model.
What I mean is that there is no relationship in Isabelle between their cost function and their actual algorithm.
The process the book goes through for a function f is the following:
1. Define `f`
2. Create a correctness predicate (call it `Correct`) and prove `forall x, Correct(f(x))`
3. Use a script to do some code generation to generate a function `time_f`
4. Prove that `time_f` fulfills some asymptotic bound (e.g. `exists c, forall x, x > c -> time_f(x) < a * x^2`)
Nowhere is `time_f` actually ever formally related to `f`. From Isabelle's point of view they are two completely separate functions that have no relationship to one another. There is only an informal, English argument given that `time_f` corresponds to `f`.
Ideally you'd be able to define some other predicate `AsymptoticallyModelsRuntime` such that `AsymptoticallyModelsRuntime(f, time_f)` holds, with the obvious semantic meaning of that predicate also holding true. But the book doesn't do that. And I don't know how they could. Hence my original question of whether there's any system that lets you write `AsymptoticallyModelsRuntime`.
Yes, I know what you mean, but there is a relationship, it is just that some of that relationship is described outside of Isabelle, but nevertheless provably. Ultimately, math is like that, provably so.
You could do what you want by making that argument explicit formally and machine-checked, but then you have to do a lot more work, by translating all of the components of the informal proof into formal ones. This will not give you any more insight than what the book already describes. But of course you could take it as an example of something that should be easy once you grasp the informal proof, but is actually quite a lot of work.