On Tue, 3 Feb 2026 10:55:05 -0300 Daniel Almeida <[email protected]> wrote:
> > On 3 Feb 2026, at 10:42, Gary Guo <[email protected]> wrote: > > > > On Tue Feb 3, 2026 at 1:33 PM GMT, Daniel Almeida wrote: > >> Hi Boris, > >> > >>> On 3 Feb 2026, at 07:39, Boris Brezillon <[email protected]> > >>> wrote: > >>> > >>> On Mon, 19 Jan 2026 12:35:21 +0000 > >>> Alice Ryhl <[email protected]> wrote: > >>> > >>>> On Mon, Jan 19, 2026 at 11:45:57AM +0100, Maxime Ripard wrote: > >>>>> On Thu, Jan 08, 2026 at 11:14:37AM -0300, Daniel Almeida wrote: > >>>>>>> For example, it's quite typical to have (at least) one clock for the > >>>>>>> bus > >>>>>>> interface that drives the register, and one that drives the main > >>>>>>> component logic. The former needs to be enabled only when you're > >>>>>>> accessing the registers (and can be abstracted with > >>>>>>> regmap_mmio_attach_clk for example), and the latter needs to be > >>>>>>> enabled > >>>>>>> only when the device actually starts operating. > >>>>>>> > >>>>>>> You have a similar thing for the prepare vs enable thing. The > >>>>>>> difference > >>>>>>> between the two is that enable can be called into atomic context but > >>>>>>> prepare can't. > >>>>>>> > >>>>>>> So for drivers that would care about this, you would create your > >>>>>>> device > >>>>>>> with an unprepared clock, and then at various times during the driver > >>>>>>> lifetime, you would mutate that state. > >>>> > >>>> The case where you're doing it only while accessing registers is > >>>> interesting, because that means the Enable bit may be owned by a local > >>>> variable. We may imagine an: > >>>> > >>>> let enabled = self.prepared_clk.enable_scoped(); > >>>> ... use registers > >>>> drop(enabled); > >>>> > >>>> Now ... this doesn't quite work with the current API - the current > >>>> Enabled stated owns both a prepare and enable count, but the above keeps > >>>> the prepare count in `self` and the enabled count in a local variable. > >>>> But it could be done with a fourth state, or by a closure method: > >>>> > >>>> self.prepared_clk.with_enabled(|| { > >>>> ... use registers > >>>> }); > >>>> > >>>> All of this would work with an immutable variable of type Clk<Prepared>. > >>>> > >>> > >>> Hm, maybe it'd make sense to implement Clone so we can have a temporary > >>> clk variable that has its own prepare/enable refs and releases them > >>> as it goes out of scope. This implies wrapping *mut bindings::clk in an > >>> Arc<> because bindings::clk is not ARef, but should be relatively easy > >>> to do. Posting the quick experiment I did with this approach, in case > >>> you're interested [1] > >>> > >>> [1]https://gitlab.freedesktop.org/bbrezillon/linux/-/commit/d5d04da4f4f6192b6e6760d5f861c69596c7d837 > >>> > >> > >> The problem with what you have suggested is that the previous state is not > >> consumed if you can clone it, and consuming the previous state is a pretty > >> key > >> element in ensuring you cannot misuse it. For example, here: > >> > >> let enabled_clk = prepared_clk.clone().enable()?; > >> // do stuff > >> // enabled_clk goes out of scope and releases the enable > >> // ref it had > >> > >> prepared_clk is still alive. Now, this may not be the end of the world in > >> this > >> particular case, but for API consistency, I'd say we should probably avoid > >> this > >> behavior. > > > > Is this an issue though? You cannot mistakenly own `Clk<Enabled>` while the > > clk > > is not enabled, (and similarly for `Prepared`), and that should be > > sufficient. > > It is not an issue. However, I just find it a bit confusing. With a > typestate, one > usually expects state transitions where a new state fully consumes the > previous > one, and that assumption is “broken” in a way when you add clone(). It's just the way clks work in practice: you having a Clk<Unprepared> doesn't mean the underlying clk_hw (the C object) is in an unprepared state, because some other users might point to the same clk_hw and have it enabled already. What Clk<State> means here is that you have a local view of a clk that's in at least this State. In order to guarantee that the clk is at least OtherState, you'll have to transition your view to this OtherState. Clone here just means you're cloning a view of this clone in its original view state. Then you're free to do whatever you want on this new view. So is the original owner of the object you clone from. > > > > > Having `Clk<Prepared>` makes no guarantee on if the clk is enabled or not > > anyway > > as you can have another user do `Clk<Unprepared>::get().enable()`. > > Although you’re right here, I find this less confusing than clone(). You > have to explicitly craft a new Clk<Enabled>, where a clone() is a shorter way > to basically get around the “state transition” idea on an _existing_ Clk > reference. The idea behind the clone() is that you can transition from one state to an higher state (prepared -> enabled for instance) for a shorter period of time than the cloned clk lifetime. Something like that, for instance: let MyDevice { prepared_clk: Clk::get(...)?.prepare()?, } implem MyDevice { fn do_stuff(&self) { let enabled_clk = self.prepared_clk.clone(); // do stuff that need to be guaranteed that clk // is enabled self.do_other_stuff(enabled_clk); // the enabled_clk object is dropped, but the // clk remains prepared because // self.prepared_clk is still there } }
