Re: [PATCH v6 2/8] drm/ttm: Add ttm_bo_access

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Am 12.11.24 um 17:33 schrieb Thomas Hellström:
[SNIP]
This has been extensively discussed already, but was expected to
really
only be needed for low-on-memory scenarios. However it now seems
like
the need is much earlier due to the random userptr page joining
by
core
mm.
Just to clarify here:
  
In Long-Running mode with recoverable pagefaults enabled we don't
have
any preempt-fences, but rather just zap the PTEs pointing to the
affected memory and flush TLB. So from a memory resource POW a
breakpoint should be safe, and no mmu notifier nor shrinker will be
blocked.
That sounds like a HMM based approach which would clearly work.

But where is that? I don't see any HMM based approach anywhere in the
XE 
driver.
This is a mode that uses recoverable pagefaults to fault either full
userptr or full bos, and used with DRM_XE_VM_CRATE_FLAG_FAULT_MODE.
(not SVM)!

userptrs in xe are bo-less, and using the vm's resv, but otherwise
using hmm similar to amdgpu: xe_hmm.c

Yeah, I have seen that one.

fault servicing:
xe_gt_pagefault.c

PTE zapping on eviction and notifier:
xe_vm_invalidate_vma(), xe_vm.c

Ah, that was the stuff I was missing.

So the implementation in xe_preempt_fence.c is just for graphics submissions? That would make the whole thing much easier to handle.

The only remaining question I can then see is if long running submissions with DRM_XE_VM_CRATE_FLAG_FAULT_MODE could potentially block graphics submissions without this flag from accessing the hardware?

Thanks a lot for pointing this out,
Christian.


Thanks,
Thomas

Regards,
Christian.

Nor will there be any jobs with published dma-fences depending on
the
job blocked either temporarily by a pagefault or long-term by a
debugger breakpoint.

/Thomas


If that is done and the memory pre-empt fence is serviced even
for
debuggable contexts, do you have further concerns with the
presented
approach
from dma-buf and drm/sched perspective?

Regards, Joonas

Regards,
Christian.


         This means that a breakpoint or core dump doesn't halt
GPU
threads, but
         rather suspends them. E.g. all running wave data is
collected into a state
         bag which can be restored later on.

         I was under the impression that those long running
compute
threads do
         exactly that, but when the hardware can't switch out
the
GPU thread/process
         while in a break then that isn't the case.

         As long as you don't find a way to avoid that this
patch
set is a pretty
         clear NAK from my side as DMA-buf and TTM maintainer.


     I believe this is addressed above.

     Matt


         What might work is to keep the submission on the
hardware
in the break state
         but forbid any memory access. This way you can signal
your
preemption fence
         even when the hardware isn't made available.

         Before you continue XE setups a new pre-emption fence
and
makes sure that
         all page tables etc... are up to date.

         Could be tricky to get this right if completion fence
based
submissions are
         mixed in as well, but that gives you at least a
direction
you could
         potentially go.

         Regards,
         Christian.


             Regards, Joonas


                 Regards,
                 Christian.


                     Some wash-up thoughts from me below, but
consider them fairly irrelevant
                     since I think the main driver for these
big
questions here should be
                     gdb/userspace.


                         Quoting Christian König (2024-11-07
11:44:33)

                             Am 06.11.24 um 18:00 schrieb
Matthew
Brost:

                                   [SNIP]

                                   This is not a generic
interface
that anyone can freely access. The same
                                   permissions used by ptrace
are
checked when opening such an interface.
                                   See [1] [2].

                                  
[1]
https://patchwork.freedesktop.org/patch/617470/?series=136572&r
e
v=2
                                  
[2]
https://patchwork.freedesktop.org/patch/617471/?series=136572&r
e
v=2


                             Thanks a lot for those pointers,
that
is exactly what I was looking for.

                             And yeah, it is what I feared. You
are
re-implementing existing functionality,
                             but see below.

                         Could you elaborate on what this
"existing
functionality" exactly is?
                         I do not think this functionality
exists at
this time.

                         The EU debugging architecture for Xe
specifically avoids the need for GDB
                         to attach with ptrace to the CPU
process or
interfere with the CPU process for
                         the debugging via parasitic threads or
so.

                         Debugger connection is opened to the
DRM
driver for given PID (which uses the
                         ptrace may access check for now) after
which the all DRM client of that
                         PID are exposed to the debugger
process.

                         What we want to expose via that
debugger
connection is the ability for GDB to
                         read/write the different GPU VM
address
spaces (ppGTT for Intel GPUs) just like
                         the EU threads would see them. Note
that
the layout of the ppGTT is
                         completely up to the userspace driver
to
setup and is mostly only partially
                         equal to the CPU address space.

                         Specifically as part of
reading/writing the
ppGTT for debugging purposes,
                         there are deep flushes needed: for
example
flushing instruction cache
                         when adding/removing breakpoints.

                         Maybe that will explain the
background. I
elaborate on this at the end some more.


                                           kmap/vmap are used
everywhere in the DRM subsystem to access BOs, so I’m
                                           failing to see the
problem with adding a simple helper based on existing
                                           code.

                                       What#s possible and
often
done is to do kmap/vmap if you need to implement a
                                       CPU copy for scanout for
example or for copying/validating command buffers.
                                       But that usually
requires
accessing the whole BO and has separate security
                                       checks.

                                       When you want to access
only
a few bytes of a BO that sounds massively like
                                       a peek/poke like
interface
and we have already rejected that more than once.
                                       There even used to be
standardized GEM IOCTLs for that which have been
                                       removed by now.

                         Referring to the explanation at top:
These
IOCTL are not for the debugging target
                         process to issue. The peek/poke
interface
is specifically for GDB only
                         to facilitate the emulation of memory
reads/writes on the GPU address
                         space as they were done by EUs
themselves.
And to recap: for modifying
                         instructions for example (add/remove
breakpoint), extra level of cache flushing is
                         needed which is not available to
regular
userspace.

                         I specifically discussed with Sima on
the
difference before moving forward with this
                         design originally. If something has
changed
since then, I'm of course happy to rediscuss.

                         However, if this code can't be added,
not
sure how we would ever be able
                         to implement core dumps for GPU
threads/memory?


                                       If you need to access
BOs
which are placed in not CPU accessible memory then
                                       implement the access
callback
for ptrace, see amdgpu_ttm_access_memory for
                                       an example how to do
this.

                         As also mentioned above, we don't work
via
ptrace at all when it comes
                         to debugging the EUs. The only thing
used
for now is the ptrace_may_access to
                         implement similar access restrictions
as
ptrace has. This can be changed
                         to something else if needed.


                                   Ptrace access via
vm_operations_struct.access → ttm_bo_vm_access.

                                   This series renames
ttm_bo_vm_access to ttm_bo_access, with no code changes.

                                   The above function accesses
a BO
via kmap if it is in SYSTEM / TT,
                                   which is existing code.

                                   This function is only
exposed to
user space via ptrace permissions.

                         Maybe this sentence is what caused the
confusion.

                         Userspace is never exposed with
peek/poke
interface, only the debugger
                         connection which is its own FD.


                                   In this series, we implement
a
function [3] similar to
                                   amdgpu_ttm_access_memory for
the
TTM vfunc access_memory. What is
                                   missing is non-visible CPU
memory
access, similar to
                                  
amdgpu_ttm_access_memory_sdma.
This will be addressed in a follow-up and
                                   was omitted in this series
given
its complexity.

                                   So, this looks more or less
identical to AMD's ptrace implementation,
                                   but in GPU address space.
Again,
I fail to see what the problem is here.
                                   What am I missing?


                             The main question is why can't you
use
the existing interfaces directly?

                         We're not working on the CPU address
space
or BOs. We're working
                         strictly on the GPU address space as
would
be seen by an EU thread if it
                         accessed address X.


                             Additional to the peek/poke
interface
of ptrace Linux has the pidfd_getfd
                             system call, see
herehttps://man7.org/linux/man-pages/man2/pidfd_getfd.2.html.

                             The pidfd_getfd() allows to dup()
the
render node file descriptor into your gdb
                             process. That in turn gives you
all the
access you need from gdb, including
                             mapping BOs and command submission
on
behalf of the application.

                         We're not operating on the CPU address
space nor are we operating on BOs
                         (there is no concept of BO in the EU
debug
interface). Each VMA in the VM
                         could come from anywhere, only the
start
address and size matter. And
                         neither do we need to interfere with
the
command submission of the
                         process under debug.


                             As far as I can see that allows
for the
same functionality as the eudebug
                             interface, just without any driver
specific code messing with ptrace
                             permissions and peek/poke
interfaces.

                             So the question is still why do
you
need the whole eudebug interface in the
                             first place? I might be missing
something, but that seems to be superfluous
                             from a high level view.

                         Recapping from above. It is to allow
the
debugging of EU threads per DRM
                         client, completely independent of the
CPU
process. If ptrace_may_acces
                         is the sore point, we could consider
other
permission checks, too. There
                         is no other connection to ptrace in
this
architecture as single
                         permission check to know if PID is
fair
game to access by debugger
                         process.

                         Why no parasitic thread or ptrace:
Going
forward, binding the EU debugging to
                         the DRM client would also pave way for
being able to extend core kernel generated
                         core dump with each DRM client's EU
thread/memory dump. We have similar
                         feature called "Offline core dump"
enabled
in the downstream public
                         trees for i915, where we currently
attach
the EU thread dump to i915 error state
                         and then later combine i915 error
state
with CPU core dump file with a
                         tool.

                         This is relatively little amount of
extra
code, as this baseline series
                         already introduces GDB the ability to
perform the necessary actions.
                         It's just the matter of kernel driver
calling: "stop all threads", then
                         copying the memory map and memory
contents
for GPU threads, just like is
                         done for CPU threads.

                         With parasitic thread injection, not
sure
if there is such way forward,
                         as it would seem to require to inject
quite
abit more logic to core kernel?


                             It's true that the AMD KFD part
has
still similar functionality, but that is
                             because of the broken KFD design
of
tying driver state to the CPU process
                             (which makes it inaccessible for
gdb
even with imported render node fd).

                             Both Sima and I (and partially
Dave as
well) have pushed back on the KFD
                             approach. And the long term plan
is to
get rid of such device driver specific
                             interface which re-implement
existing
functionality just differently.

                         Recapping, this series is not adding
it
back. The debugger connection
                         is a separate FD from the DRM one,
with
separate IOCTL set. We don't allow
                         the DRM FD any new operations based on
ptrace is attached or not. We
                         don't ever do that check even.

                         We only restrict the opening of the
debugger connection to given PID with
                         ptrace_may_access check for now. That
can
be changed to something else,
                         if necessary.

                     Yeah I think unnecessarily tying gpu
processes
to cpu processes is a bad
                     thing, least because even today all the
svm
discussions we have still hit
                     clear use-cases, where a 1:1 match is not
wanted (like multiple gpu svm
                     sections with offsets). Not even speaking
of
all the gpu usecases where
                     the gpu vm space is still entirely
independent
of the cpu side.

                     So that's why I think this entirely
separate
approach looks like the right
                     one, with ptrace_may_access as the access
control check to make sure we
                     match ptrace on the cpu side.

                     But there's very obviously a bikeshed to
be had
on what the actual uapi
                     should look like, especially how gdb opens
up a
gpu debug access fd. But I
                     also think that's not much on drm to
decide,
but whatever gdb wants. And
                     then we aim for some consistency on that
lookup/access control part
                     (ideally, I might be missing some reasons
why
this is a bad idea) across
                     drm drivers.


                             So you need to have a really
really
good explanation why the eudebug interface
                             is actually necessary.

                         TL;DR The main point is to decouple
the
debugging of the EU workloads from the
                         debugging of the CPU process. This
avoids
the interference with the CPU process with
                         parasitic thread injection. Further
this
also allows generating a core dump
                         without any GDB connected. There are
also
many other smaller pros/cons
                         which can be discussed but for the
context
of this patch, this is the
                         main one.

                         So unlike parasitic thread injection,
we
don't unlock any special IOCTL for
                         the process under debug to be
performed by
the parasitic thread, but we
                         allow the minimal set of operations to
be
performed by GDB as if those were
                         done on the EUs themselves.

                         One can think of it like the minimal
subset
of ptrace but for EU threads,
                         not the CPU threads. And thus,
building on
this it's possible to extend
                         the core kernel generated core dumps
with
DRM specific extension which
                         would contain the EU thread/memory
dump.

                     It might be good to document (in that
debugging
doc patch probably) why
                     thread injection is not a great option,
and why
the tradeoffs for
                     debugging are different than for for
checkpoint/restore, where with CRIU
                     we landed on doing most of this in
userspace,
and often requiring
                     injection threads to make it all work.

                     Cheers, Sima


                         Regards, Joonas


                             Regards,
                             Christian.



                                   Matt

                                  
[3]
https://patchwork.freedesktop.org/patch/622520/?series=140200&r
e
v=6


                                       Regards,
                                       Christian.


                                           Matt


                                               Regards,
                                               Christian.




      

    


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