From mboxrd@z Thu Jan 1 00:00:00 1970 From: Alexander Graf Date: Mon, 22 Feb 2016 21:09:41 +0100 Subject: [U-Boot] [PATCH 0/9] arm64: Unify MMU code In-Reply-To: References: <1456106232-233210-1-git-send-email-agraf@suse.de> <14FCFFD6-8691-43C6-AD6A-DAB535E61586@suse.de> <0AD586D5-1E50-4B33-B77D-24A42761515A@suse.de> <56CB6493.1000804@suse.de> Message-ID: <56CB6B05.5050400@suse.de> List-Id: MIME-Version: 1.0 Content-Type: text/plain; charset="us-ascii" Content-Transfer-Encoding: 7bit To: u-boot@lists.denx.de On 22.02.16 20:52, york sun wrote: > On 02/22/2016 11:42 AM, Alexander Graf wrote: >> >> >> On 22.02.16 19:39, york sun wrote: >>> On 02/22/2016 10:31 AM, Alexander Graf wrote: >>>> >>>> On Feb 22, 2016, at 7:12 PM, york sun wrote: >>>> >>>>> On 02/22/2016 10:02 AM, Alexander Graf wrote: >>>>>> >>>>>> >>>>>>> Am 22.02.2016 um 18:37 schrieb york sun : >>>>>>> >>>>>>>> On 02/21/2016 05:57 PM, Alexander Graf wrote: >>>>>>>> Howdy, >>>>>>>> >>>>>>>> Currently on arm64 there is a big pile of mess when it comes to MMU >>>>>>>> support and page tables. Each board does its own little thing and the >>>>>>>> generic code is pretty dumb and nobody actually uses it. >>>>>>>> >>>>>>>> This patch set tries to clean that up. After this series is applied, >>>>>>>> all boards except for the FSL Layerscape ones are converted to the >>>>>>>> new generic page table logic and have icache+dcache enabled. >>>>>>>> >>>>>>>> The new code always uses 4k page size. It dynamically allocates 1G or >>>>>>>> 2M pages for ranges that fit. When a dcache attribute request comes in >>>>>>>> that requires a smaller granularity than our previous allocation could >>>>>>>> fulfill, pages get automatically split. >>>>>>>> >>>>>>>> I have tested and verified the code works on HiKey (bare metal), >>>>>>>> vexpress64 (Foundation Model) and zynqmp (QEMU). The TX1 target is >>>>>>>> untested, but given the simplicity of the maps I doubt it'll break. >>>>>>>> ThunderX in theory should also work, but I haven't tested it. I would >>>>>>>> be very happy if people with access to those system could give the patch >>>>>>>> set a try. >>>>>>>> >>>>>>>> With this we're a big step closer to a good base line for EFI payload >>>>>>>> support, since we can now just require that all boards always have dcache >>>>>>>> enabled. >>>>>>>> >>>>>>>> I would also be incredibly happy if some Freescale people could look >>>>>>>> at their MMU code and try to unify it into the now cleaned up generic >>>>>>>> code. I don't think we're far off here. >>>>>>> >>>>>>> Alex, >>>>>>> >>>>>>> Unified MMU will be great for all of us. The reason we started with our own MMU >>>>>>> table was size and performance. I don't know much about other ARMv8 SoCs. For >>>>>>> our use, we enable cache very early to speed up running, especially for >>>>>>> pre-silicon development on emulators. We don't have DDR to use for the early >>>>>>> stage and we have very limited on-chip SRAM. I believe we can use the unified >>>>>>> structure for our 2nd stage MMU when DDR is up. >>>>>> >>>>>> Yup, and I think it should be fairly doable to move the early generation into the same table format - maybe even fully reuse the generic code. >>>>> >>>>> What's the size for the MMU tables? I think it may be simpler to use static >>>>> tables for our early stage. >>>> >>>> The size is determined dynamically from the memory map using some code that (as Steven found) is not 100% sound, but works well enough so far :). >>> >>> That's the part I can't live with. Since we have very limited on-chip RAM, we >>> have to know limit the size. But again, I do see the benefit to use unified >>> structure for the 2nd stage. >> >> I'm not quite sure I see how your current code works any differently. >> While the code to determine the page table pool size is dynamic, the >> outcome is static depending on your memory map. So the same memory map >> always means the same page table pool size. >> >> We could also just hard code the size for the early phase for you I guess. > > We can definitely try. > >> >>> >>>> >>>>> >>>>>> >>>>>> The thing that I tripped over while attempting conversion was that you don't always map phys==virt, unless other boards, and I didn't fully understand why. >>>>>> >>>>> True. We have some complication on the address mapping. For compatibility, each >>>>> device is mapped (partially) under 32-bit space. If the device is too large to >>>> >>>> Compatibility with what? Do we really need this in an AArch64 world? >>> >>> It's not up to me. The SoC was designed this way. By the way, this SoC can work >>> in AArch32 mode. >> >> I think I'm slowly grasping what the problem is. >> >> The fact that the SoC can run in AArch32 mode doesn't actually make a >> difference here though, since we're talking about U-Boot internal memory >> maps. The only reason to keep things mapped reachable from 32bits is if >> you want to run 32bit code with the U-Boot maps. I don't think you'd >> want to do that, no? :) > > I don't really want to run 32-bit code. My point is the SoC was designed that > way. We have DDR under 32-bit space, and in high region. We have the same for > flash controller where NOR is connected. Explained later below. >> >>> >>>> >>>> For 32bit code I can definitely understand why you'd want to have phys != virt. But in a pure 64bit world (which this target really is, no?) I see little benefit on it. >>>> >>>>> fit, the rest is mapped to high regions. I remember one particular case on top >>>>> of my head. It is the NOR flash we use for environmental variables. U-boot uses >>>>> that address for saving, but also uses that for loading during booting. For our >>>>> case, the NOR flash doesn't fit well in the low region, so it is remapped to >>>>> high region after booting. To make the environmental variables accessible during >>>>> boot, we mapped the high region phys with different virt, so u-boot doesn't have >>>>> to know the low region address. >>>> >>>> I might be missing the obvious, but why can't the environmental variables live in high regions? >>>> >>> >>> It is in high region. But as I tried to explain, the default physical mapping of >>> NOR flash (not MMU) is in low region out of reset. >> >> I see. So the problem is during the transitioning phase from uncached to >> MMU enabled, where we'd end up at a different address. > > Not exactly. We enable cache very early for performance boost on emulator. It > may sound trivial but it makes big difference when debugging software on > emulators. Since we still use emulators for new product, I am not ready to drop > the early MMU approach. I'm surprised it is that slow for you. Running the Foundation model (which doesn't do early mmu FWIW) seemed to be fast enough. > But you get the idea, the difference is before and after relocation. After > u-boot relocates itself into DDR, we remap flash controller physical address to > high region. > >> >> Could we just configure NOR to be in high memory in early asm init code, >> then always use the high physical NOR address range and jump to it from >> asm very early on? Then we could ignore the 32bit map and everything >> could just stay 1:1 mapped. >> > > Out of reset, if booting from NOR flash, the flash controller is pre-configured > to use low region address. We can only reprogram the controller when u-boot is > not running on it. I see, so you keep the low map alive until you make the switch-over to DDR. Makes a lot of sense. I guess I can give the conversion another stab now whenever I get a free night :). If I understand you correctly we'd only need to do non-1:1 maps for the early code, right? > I see you are trying to maintain the 1:1 mapping for MMU. Why so? I think the > framework should allow different mapping. Mostly for the sake of simplicity. It wouldn't be very different to extend the logic to support setting of va != pa, but I find code vastly easier to debug and understand if the address I see is the address I access. Alex