Re: git: 060699e91369 - stable/13 - Merge llvm-project release/15.x llvmorg-15.0.7-0-g8dfdcc7b7bf6
- Reply: Jason A. Harmening: "Re: git: 060699e91369 - stable/13 - Merge llvm-project release/15.x llvmorg-15.0.7-0-g8dfdcc7b7bf6"
- In reply to: John Baldwin : "Re: git: 060699e91369 - stable/13 - Merge llvm-project release/15.x llvmorg-15.0.7-0-g8dfdcc7b7bf6"
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Date: Mon, 01 May 2023 18:41:32 UTC
On 1 May 2023, at 18:14, John Baldwin <jhb@freebsd.org> wrote: > > On 4/30/23 8:31 PM, Jason A. Harmening wrote: >> On Sun, Apr 30, 2023 at 07:34:45PM -0500, Jason A. Harmening wrote: >>> On Sun, Apr 30, 2023 at 06:47:13PM -0500, Jason A. Harmening wrote: >>>> On Sun, Apr 30, 2023 at 08:09:16AM +0300, Konstantin Belousov wrote: >>>>> On Sat, Apr 29, 2023 at 02:27:50PM -0500, Jason A. Harmening wrote: >>>>>> On Sat, Apr 29, 2023 at 08:49:28PM +0200, Dimitry Andric wrote: >>>>>>> On 29 Apr 2023, at 20:33, Jason A. Harmening <jah@FreeBSD.org> wrote: >>>>>>>> >>>>>>>> On Sun, Apr 09, 2023 at 09:35:22PM +0000, Dimitry Andric wrote: >>>>>>>>> The branch stable/13 has been updated by dim: >>>>>>>>> >>>>>>>>> URL: https://cgit.FreeBSD.org/src/commit/?id=060699e9136975d51d3f726b9785bdbac9a62ba6 >>>>>>>>> >>>>>>>>> commit 060699e9136975d51d3f726b9785bdbac9a62ba6 >>>>>>>>> Author: Dimitry Andric <dim@FreeBSD.org> >>>>>>>>> AuthorDate: 2023-01-14 16:33:24 +0000 >>>>>>>>> Commit: Dimitry Andric <dim@FreeBSD.org> >>>>>>>>> CommitDate: 2023-04-09 14:54:52 +0000 >>>>>>>>> >>>>>>>>> Merge llvm-project release/15.x llvmorg-15.0.7-0-g8dfdcc7b7bf6 >>>>>>>>> >>>>>>>>> This updates llvm, clang, compiler-rt, libc++, libunwind, lld, lldb and >>>>>>>>> openmp to llvmorg-15.0.7-0-g8dfdcc7b7bf6. >>>>>>>>> >>>>>>>>> PR: 265425 >>>>>>>>> MFC after: 2 weeks >>>>>>>> >>>>>>>> This MFC of llvm15 appears to have completely broken the Intel IOMMU >>>>>>>> driver on my stable/13 machine. After this series of commits, any >>>>>>>> downstream DMA seems to produce an IOMMU translation fault, which >>>>>>>> renders the machine completely unusable: no nvme boot disk, no usb >>>>>>>> keyboard, etc. >>>>>>>> >>>>>>>> The faults I see look something like this: >>>>>>>> >>>>>>>> DMAR4: ahci0: pci0:17:5 sid 8d fault acc 0 adt 0x0 reason 0x3 addr 26000 >>>>>>>> >>>>>>>> It's a bit surprising to see a toolchain upgrade produce breakage like >>>>>>>> this, but that's what git bisect clearly tells me. I wonder if some of >>>>>>>> the IOMMU control structures might be defined as C bitfields and the new >>>>>>>> compiler is emitting them differently? Also, was any breakage like this >>>>>>>> observed when -current was upgraded to llvm15 several months ago? >>>>>>> >>>>>>> I haven't heard anything about such breakage, no. >>>>>>> >>>>>>> >>>>>>>> More generally, this is the second time in as many months I've had to >>>>>>>> deal with IOMMU breakage on -stable. I can't imagine I'm the only >>>>>>>> person who sees value in running with DMA remapping enabled; do we need >>>>>>>> a dedicated DMAR-enabled machine in the cluster to smoke-test changes >>>>>>>> like this? More generally, should we avoid MFCing high-risk changes >>>>>>>> like this? >>>>>>> >>>>>>> Since there were very few bug reports, it was not deemed high risk. >>>>>>> >>>>>>> In any case, it would be good to get the bottom of what is causing the >>>>>>> problem, so is there any way you can isolate which code seems to be >>>>>>> going "bad"? >>>>>>> >>>>>>> For example, if this problem affects code in sys/dev/iommu, is there >>>>>>> some way you can compile that part with -O1, or with an older version >>>>>>> of clang (from ports), to see if the problem goes away? >>>>>> >>>>>> I did try removing all custom make.conf settings (previously I just had >>>>>> CPUTYPE?=icelake-server), but that didn't change the behavior. >>>>>> >>>>>> Before I try further build tweaks, I'd like to ask if the IOMMU fault >>>>>> report can provide guidance here? AFAICT all the faults I'm getting >>>>>> show "reason 0x3". If I'm reading the VT-d spec correctly, FR=0x3 >>>>>> indicates an invalid context entry, in other words there's something the >>>>>> hardware doesn't like in the way the address width or pagetable base is >>>>>> configured for the PCIe requestor. >>>>> >>>>> I would start looking at the other direction: might be, there are still some >>>>> left shifts for int32 values with the shift count > 30, or uint32 with the >>>>> count > 31. >>>>> >>>>> Also might be useful to dump each context entry on creation, it is kept >>>>> constant after. >>>> >>>> I did look over the constants in intel_reg.h, and didn't see anything >>>> that looked as though it would be susceptible to sign-extension or >>>> truncation bugs. In the failing case it's much easier for me to catch >>>> the fault messages than any initialization message, so I instrumented >>>> the fault handler to get the context entry from the dmar_ctx object >>>> using the same logic as dmar_map_ctx_entry(), and then dump out the ctx1 >>>> and ctx2 fields. What I see are messages like: >>>> >>>> ... ctx1 0x10013b001 ctx2 0x103 >>>> >>>> At first glance these "look right": the P bit is set in ctx1, and the >>>> rest of the field looks like a valid physical address. ctx2 also >>>> doesn't have any of the reserved bits set, but in all cases it does have >>>> AW=3, which would indicate 57-bit AGAW. But when I boot the last >>>> working kernel, from the revision prior to the llvm15 MFC, I see this in >>>> dmesg: >>>> >>>> ahci0: dmar4 pci0:0:17:5 rid 8d domain 1 mgaw 48 agaw 48 re-mapped >>>> >>>> ...all reported devices show 48-bit MGAW/AGAW, so I would expect ctx2 to >>>> have AW=2. I suspect this may be the source of the fault, but I'm not >>>> sure how it's getting configured that way, whether it's an issue with >>>> reading the capability register or something else. >>>> >>> >>> I can confirm that hacking domain_set_agaw() to always use the settings >>> from sagaw_bits[2] eliminates the faults and at least allows the machine >>> to boot to single-user mode. >> I see what's happening now. When I added the hack to always set >> sagaw_bits[2], I noted that the passed-in MGAW was still 57, while >> unit->hw_cap had the correct value of 0x4 (=> 4-level paging, 48-bit AW) >> in bits 12:8. The problem is that sagaw_bits has agaw=64 in its last >> entry. This results in dmar_maxaddr2mgaw() attempting a comparison >> against 1ULL << 64 in the final iteration of its first loop. I suspect >> the new compiler probably determines that last iteration is meaningless >> and simply omits it from the (probably unrolled) loop. Since the "loop" >> terminates with i < nitems(sagaw_bits), the subsequent "allow_less ..." >> case doesn't execute and we end up erroneously selecting a 57-bit >> address width. Just commenting out that last entry in sagaw_bits fixes >> the problem. >> So, two questions: >> 1) Does any VT-d hardware actually support 6-level paging? The ca. 2021 >> VT-d spec I'm looking at indicates 5-level is the greatest depth >> supported, with everything above that being reserved. >> 2) I'd expect clang to try very hard to error out in a situation like >> this, but I see that sys/conf/kern.mk sets -Wno-shift-count-overflow >> among other things, and more of them were added for clang 15. This >> seems like a really bad idea, regardless of how much of a PITA it may be >> to fix these warnings. > > FWIW, I've been working on trying to re-enable some of the warnings that > were disabled for clang 15 in main. I'll move that one higher up on my > todo list. In this particular case, it doesn't warn about it though. I think KASAN might be a better 'catcher' for this kind of error, or a KUBSAN, if we had one... -Dimitry