On Wednesday 07 January 2015 12:44:56 Jon Masters wrote:
On 01/07/2015 12:27 PM, Mark Brown wrote:
On Wed, Jan 07, 2015 at 02:06:28PM +0100, Arnd Bergmann wrote:
On Wednesday 07 January 2015 11:50:39 Catalin Marinas wrote:
From what I gathered so far, the main reason for _some_ vendors is not support for "other" OS but actually features that ACPI has and DT doesn't (like AML; I deliberately ignore statements like "industry standard"). _If_ such reasons are sound, maybe they have a case for ACPI-only machines targeted primarily at Linux.
What I got from the replies from HP, Huawei and from earlier discussions with Jon is that they all hope to get to the point of relying on AML alone to bridge the differences between SoC families.
I'm expecting to need new drivers for SoC IP blocks that are net new, but generational differences between iterations of the same SoC should be abstracted behind the firmware (and we are already seeing this with at least one platform). Platform wise, it's nice to already see e.g. mmconfig working to handle the specific ways a platform wires PCI.
Yes, the parts that are mandated by SBSA, like the way that PCI needs to be done are generally good. Unfortunately a lot of the hardware that I've seen has a rather lax interpretation of the spec, so just because something is mandated doesn't mean it's done that way ;-)
In other cases that's actually a good thing. One such example is the "Principles of ARM Memory Maps" document that tells hardware implementers to do a rather complex mapping "To support 36-bit x86 PAE compatible operating systems, such as Linux." but makes life much harder in the process than any of the random mappings we have seen in the wild.
I tend to agree with you that it's an overreach to think that this is going to completely abstract away the differences between SoCs from different vendors without substantial further standardization work.
(which we plan to do - I intend ultimately for us to have an answer to the Windows Hardware Qualification guides for ARM server systems)
Ok, good.
The main problem here is that can AML only cover part of the problem: it can talk to a clock controller e.g. over I2C, SPI, GPIO, UART or IPMI, but you still need a device driver in the kernel to talk to those, and SBSA doesn't mandate a specific implementation so you can expect every other SoC that is coming out to have a different one.
Similarly, SBSA is rather vague about some peripherals it mandates, and if a new SoC has a slightly different AHCI variation, there is nothing you can do about it in AML.
x86 gets around this problem by having an extreme level of hardware backwards compatibility, so you don't even need AML for this and can generally boot a (almost) full-featured Linux kernel with acpi=off on the command line.
That level of hardware compatibility does partly come from the need to run existing software. I'd expect that similar effects will start to come into play with ARMv8 ACPI systems if they become successful; people will do things like ensure compatibility with common IPs that have existing Linux drivers that distros tend to include as standard.
Agreed.
There are two problems I see in trying to do the same thing on ARM:
* we don't have a single vendor that makes de-facto standards that everyone else has to copy in the way that the few remaining x86 vendors copy everything that Intel does. In fact, we prefer to have a large number of independent vendors.
* There is a general mindset about deprecating unwanted features early. ARMv8 aarch32 bit mode removes support for older instructions or makes them optional. Even the virtualization mode doesn't allow to trap on architecture version specific differences, so you can't completely emulate an older architecture level. This is nice for implementers but not so much for users that rely on old (mis-)features. It's also not just the CPU core, other components also get easily replaced, like a GICv3 that is not a strict superset of GICv2.
Arnd