On Mon, Feb 18, 2019 at 5:30 PM Will Deacon <will.deacon@xxxxxxx> wrote: > > On Tue, Feb 12, 2019 at 02:03:04PM +0100, Arnd Bergmann wrote: > > On Mon, Feb 11, 2019 at 6:29 PM Will Deacon <will.deacon@xxxxxxx> wrote: > > > > > + __iomem pointers obtained with non-default attributes (e.g. those returned > > > + by ioremap_wc()) are unlikely to provide many of these guarantees. If > > > + ordering is required for such mappings, then the mandatory barriers should > > > + be used in conjunction with the _relaxed() accessors defined below. > > > > I wonder if we are even able to guarantee consistent behavior across > > architectures > > in the last case here (wc mapping with relaxed accessors and barriers). > > > > Fortunately, there are only five implementations that actually differ from > > ioremap_nocache(): arm32, arm64, ppc32, ppc64 and x86 (both 32/64), so > > that is something we can probably figure out between the people on Cc. > ... > > The problem with recommending *_relaxed() + barrier() is that it ends > > up being more expensive than the non-relaxed accessors whenever > > _relaxed() implies the barrier already (true on most architectures other > > than arm). > > > > ioremap_wc() in turn is used almost exclusively to map RAM behind > > a bus, (typically for frame buffers) and we may be better off not > > assuming any particular MMIO barrier semantics for it at all, but possibly > > audit the few uses that are not frame buffers. > > Right, my expectation is actually that you very rarely need ordering > guarantees for wc mappings, and so saying "relaxed + mandatory barriers" > is the best thing to say for portable driver code. I'm deliberately /not/ > trying to enumerate arch or device-specific behaviours. That's fine, my worry is more that you are already saying too much by describing a behavior for ioremap_wc+relaxed+barrier that is neither a good idea or guaranteed to do what you describe. > > > + Since many CPU architectures ultimately access these peripherals via an > > > + internal virtual memory mapping, the portable ordering guarantees provided > > > + by inX() and outX() are the same as those provided by readX() and writeX() > > > + respectively when accessing a mapping with the default I/O attributes. > > > > This is notably weaker than the PCI mandated non-posted write semantics. > > As I said earlier, not all architectures or PCI host implementations can provide > > non-posted writes though, but maybe we can document that fact here, e.g. > > > > | Device drivers may expect outX() to be a non-posted write, i.e. waiting for > > | a completion response from the I/O device, which may not be possible > > | on a particular hardware. > > I can add something along these lines, since this seems like it could be a > bit of a "gotcha" given the macro names and implicit x86 heritage. Ok. > > > (*) ioreadX(), iowriteX() > > > > > > These will perform appropriately for the type of access they're actually > > > doing, be it inX()/outX() or readX()/writeX(). > > > > This probably needs clarification as well then: On architectures that > > have a stronger barrier after outX() than writeX() but that use memory > > mapped access for both, the statement is currently not true. We could > > either strengthen the requirement by requiring CONFIG_GENERIC_IOMAP > > on such architectures, or we could document the current behavior > > as intentional and explicitly not allow iowriteX() on I/O ports to be posted. > > At least on arm and arm64, the heavy barrier in outX() is *before* the I/O > access, and so it does nothing to prevent the access from being posted. It > looks like the asm-generic/io.h behaviour is the same in the case that none > of the __io_* barriers are provided by the architecture. > > Do you think this is something we actually need to strengthen, or are > drivers that rely on this going to be x86-specific anyway? I would say we should strengthen the behavior of outX() where possible. I don't know if arm64 actually has a way of doing that, my understanding earlier was that the AXI bus was already posted, so there is not much you can do here to define __io_paw() in a way that will prevent posted writes. > > > +All of these accessors assume that the underlying peripheral is little-endian, > > > +and will therefore perform byte-swapping operations on big-endian architectures. > > > > This sounds like a useful addition and the only sane way to do it IMHO, but > > I think at least traditionally we've had architectures that do not work like > > this but that make readX()/writeX() do native big-endian loads and stores, with > > a hardware byteswap on the PCI bus. > > Sure, hence my disclaimer at the beginning about non-portable drivers :) > My goal here is really to document the portable semantics for the common > architectures, so that driver developers and reviewers can get the usual > case right. Fair enough. Arnd