linux/Documentation/gpu/rfc/i915_vm_bind.rst

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I915 VM_BIND feature design and use cases
==========================================
VM_BIND feature
================
DRM_I915_GEM_VM_BIND/UNBIND ioctls allows UMD to bind/unbind GEM buffer
objects (BOs) or sections of a BOs at specified GPU virtual addresses on a
specified address space (VM). These mappings (also referred to as persistent
mappings) will be persistent across multiple GPU submissions (execbuf calls)
issued by the UMD, without user having to provide a list of all required
mappings during each submission (as required by older execbuf mode).
The VM_BIND/UNBIND calls allow UMDs to request a timeline out fence for
signaling the completion of bind/unbind operation.
VM_BIND feature is advertised to user via I915_PARAM_VM_BIND_VERSION.
User has to opt-in for VM_BIND mode of binding for an address space (VM)
during VM creation time via I915_VM_CREATE_FLAGS_USE_VM_BIND extension.
VM_BIND/UNBIND ioctl calls executed on different CPU threads concurrently are
not ordered. Furthermore, parts of the VM_BIND/UNBIND operations can be done
asynchronously, when valid out fence is specified.
VM_BIND features include:
* Multiple Virtual Address (VA) mappings can map to the same physical pages
of an object (aliasing).
* VA mapping can map to a partial section of the BO (partial binding).
* Support capture of persistent mappings in the dump upon GPU error.
* Support for userptr gem objects (no special uapi is required for this).
TLB flush consideration
------------------------
The i915 driver flushes the TLB for each submission and when an object's
pages are released. The VM_BIND/UNBIND operation will not do any additional
TLB flush. Any VM_BIND mapping added will be in the working set for subsequent
submissions on that VM and will not be in the working set for currently running
batches (which would require additional TLB flushes, which is not supported).
Execbuf ioctl in VM_BIND mode
-------------------------------
A VM in VM_BIND mode will not support older execbuf mode of binding.
The execbuf ioctl handling in VM_BIND mode differs significantly from the
older execbuf2 ioctl (See struct drm_i915_gem_execbuffer2).
Hence, a new execbuf3 ioctl has been added to support VM_BIND mode. (See
struct drm_i915_gem_execbuffer3). The execbuf3 ioctl will not accept any
execlist. Hence, no support for implicit sync. It is expected that the below
work will be able to support requirements of object dependency setting in all
use cases:
"dma-buf: Add an API for exporting sync files"
(https://lwn.net/Articles/859290/)
The new execbuf3 ioctl only works in VM_BIND mode and the VM_BIND mode only
works with execbuf3 ioctl for submission. All BOs mapped on that VM (through
VM_BIND call) at the time of execbuf3 call are deemed required for that
submission.
The execbuf3 ioctl directly specifies the batch addresses instead of as
object handles as in execbuf2 ioctl. The execbuf3 ioctl will also not
support many of the older features like in/out/submit fences, fence array,
default gem context and many more (See struct drm_i915_gem_execbuffer3).
In VM_BIND mode, VA allocation is completely managed by the user instead of
the i915 driver. Hence all VA assignment, eviction are not applicable in
VM_BIND mode. Also, for determining object activeness, VM_BIND mode will not
be using the i915_vma active reference tracking. It will instead use dma-resv
object for that (See `VM_BIND dma_resv usage`_).
So, a lot of existing code supporting execbuf2 ioctl, like relocations, VA
evictions, vma lookup table, implicit sync, vma active reference tracking etc.,
are not applicable for execbuf3 ioctl. Hence, all execbuf3 specific handling
should be in a separate file and only functionalities common to these ioctls
can be the shared code where possible.
VM_PRIVATE objects
-------------------
By default, BOs can be mapped on multiple VMs and can also be dma-buf
exported. Hence these BOs are referred to as Shared BOs.
During each execbuf submission, the request fence must be added to the
dma-resv fence list of all shared BOs mapped on the VM.
VM_BIND feature introduces an optimization where user can create BO which
is private to a specified VM via I915_GEM_CREATE_EXT_VM_PRIVATE flag during
BO creation. Unlike Shared BOs, these VM private BOs can only be mapped on
the VM they are private to and can't be dma-buf exported.
All private BOs of a VM share the dma-resv object. Hence during each execbuf
submission, they need only one dma-resv fence list updated. Thus, the fast
path (where required mappings are already bound) submission latency is O(1)
w.r.t the number of VM private BOs.
VM_BIND locking hierarchy
-------------------------
The locking design here supports the older (execlist based) execbuf mode, the
newer VM_BIND mode, the VM_BIND mode with GPU page faults and possible future
system allocator support (See `Shared Virtual Memory (SVM) support`_).
The older execbuf mode and the newer VM_BIND mode without page faults manages
residency of backing storage using dma_fence. The VM_BIND mode with page faults
and the system allocator support do not use any dma_fence at all.
VM_BIND locking order is as below.
1) Lock-A: A vm_bind mutex will protect vm_bind lists. This lock is taken in
vm_bind/vm_unbind ioctl calls, in the execbuf path and while releasing the
mapping.
In future, when GPU page faults are supported, we can potentially use a
rwsem instead, so that multiple page fault handlers can take the read side
lock to lookup the mapping and hence can run in parallel.
The older execbuf mode of binding do not need this lock.
2) Lock-B: The object's dma-resv lock will protect i915_vma state and needs to
be held while binding/unbinding a vma in the async worker and while updating
dma-resv fence list of an object. Note that private BOs of a VM will all
share a dma-resv object.
The future system allocator support will use the HMM prescribed locking
instead.
3) Lock-C: Spinlock/s to protect some of the VM's lists like the list of
invalidated vmas (due to eviction and userptr invalidation) etc.
When GPU page faults are supported, the execbuf path do not take any of these
locks. There we will simply smash the new batch buffer address into the ring and
then tell the scheduler run that. The lock taking only happens from the page
fault handler, where we take lock-A in read mode, whichever lock-B we need to
find the backing storage (dma_resv lock for gem objects, and hmm/core mm for
system allocator) and some additional locks (lock-D) for taking care of page
table races. Page fault mode should not need to ever manipulate the vm lists,
so won't ever need lock-C.
VM_BIND LRU handling
---------------------
We need to ensure VM_BIND mapped objects are properly LRU tagged to avoid
performance degradation. We will also need support for bulk LRU movement of
VM_BIND objects to avoid additional latencies in execbuf path.
The page table pages are similar to VM_BIND mapped objects (See
`Evictable page table allocations`_) and are maintained per VM and needs to
be pinned in memory when VM is made active (ie., upon an execbuf call with
that VM). So, bulk LRU movement of page table pages is also needed.
VM_BIND dma_resv usage
-----------------------
Fences needs to be added to all VM_BIND mapped objects. During each execbuf
submission, they are added with DMA_RESV_USAGE_BOOKKEEP usage to prevent
over sync (See enum dma_resv_usage). One can override it with either
DMA_RESV_USAGE_READ or DMA_RESV_USAGE_WRITE usage during explicit object
dependency setting.
Note that DRM_I915_GEM_WAIT and DRM_I915_GEM_BUSY ioctls do not check for
DMA_RESV_USAGE_BOOKKEEP usage and hence should not be used for end of batch
check. Instead, the execbuf3 out fence should be used for end of batch check
(See struct drm_i915_gem_execbuffer3).
Also, in VM_BIND mode, use dma-resv apis for determining object activeness
(See dma_resv_test_signaled() and dma_resv_wait_timeout()) and do not use the
older i915_vma active reference tracking which is deprecated. This should be
easier to get it working with the current TTM backend.
Mesa use case
--------------
VM_BIND can potentially reduce the CPU overhead in Mesa (both Vulkan and Iris),
hence improving performance of CPU-bound applications. It also allows us to
implement Vulkan's Sparse Resources. With increasing GPU hardware performance,
reducing CPU overhead becomes more impactful.
Other VM_BIND use cases
========================
Long running Compute contexts
------------------------------
Usage of dma-fence expects that they complete in reasonable amount of time.
Compute on the other hand can be long running. Hence it is appropriate for
compute to use user/memory fence (See `User/Memory Fence`_) and dma-fence usage
must be limited to in-kernel consumption only.
Where GPU page faults are not available, kernel driver upon buffer invalidation
will initiate a suspend (preemption) of long running context, finish the
invalidation, revalidate the BO and then resume the compute context. This is
done by having a per-context preempt fence which is enabled when someone tries
to wait on it and triggers the context preemption.
User/Memory Fence
~~~~~~~~~~~~~~~~~~
User/Memory fence is a <address, value> pair. To signal the user fence, the
specified value will be written at the specified virtual address and wakeup the
waiting process. User fence can be signaled either by the GPU or kernel async
worker (like upon bind completion). User can wait on a user fence with a new
user fence wait ioctl.
Here is some prior work on this:
https://patchwork.freedesktop.org/patch/349417/
Low Latency Submission
~~~~~~~~~~~~~~~~~~~~~~~
Allows compute UMD to directly submit GPU jobs instead of through execbuf
ioctl. This is made possible by VM_BIND is not being synchronized against
execbuf. VM_BIND allows bind/unbind of mappings required for the directly
submitted jobs.
Debugger
---------
With debug event interface user space process (debugger) is able to keep track
of and act upon resources created by another process (debugged) and attached
to GPU via vm_bind interface.
GPU page faults
----------------
GPU page faults when supported (in future), will only be supported in the
VM_BIND mode. While both the older execbuf mode and the newer VM_BIND mode of
binding will require using dma-fence to ensure residency, the GPU page faults
mode when supported, will not use any dma-fence as residency is purely managed
by installing and removing/invalidating page table entries.
Page level hints settings
--------------------------
VM_BIND allows any hints setting per mapping instead of per BO. Possible hints
include placement and atomicity. Sub-BO level placement hint will be even more
relevant with upcoming GPU on-demand page fault support.
Page level Cache/CLOS settings
-------------------------------
VM_BIND allows cache/CLOS settings per mapping instead of per BO.
Evictable page table allocations
---------------------------------
Make pagetable allocations evictable and manage them similar to VM_BIND
mapped objects. Page table pages are similar to persistent mappings of a
VM (difference here are that the page table pages will not have an i915_vma
structure and after swapping pages back in, parent page link needs to be
updated).
Shared Virtual Memory (SVM) support
------------------------------------
VM_BIND interface can be used to map system memory directly (without gem BO
abstraction) using the HMM interface. SVM is only supported with GPU page
faults enabled.
VM_BIND UAPI
=============
.. kernel-doc:: Documentation/gpu/rfc/i915_vm_bind.h