[Intel-gfx] [PATCH 7/7] dma-resv: Give the docs a do-over

Matthew Auld matthew.william.auld at gmail.com
Tue Jul 6 12:34:40 UTC 2021


On Tue, 6 Jul 2021 at 11:12, Daniel Vetter <daniel.vetter at ffwll.ch> wrote:
>
> Specifically document the new/clarified rules around how the shared
> fences do not have any ordering requirements against the exclusive
> fence.
>
> But also document all the things a bit better, given how central
> struct dma_resv to dynamic buffer management the docs have been very
> inadequat.
>
> - Lots more links to other pieces of the puzzle. Unfortunately
>   ttm_buffer_object has no docs, so no links :-(
>
> - Explain/complain a bit about dma_resv_locking_ctx(). I still don't
>   like that one, but fixing the ttm call chains is going to be
>   horrible. Plus we want to plug in real slowpath locking when we do
>   that anyway.
>
> - Main part of the patch is some actual docs for struct dma_resv.
>
> Overall I think we still have a lot of bad naming in this area (e.g.
> dma_resv.fence is singular, but contains the multiple shared fences),
> but I think that's more indicative of how the semantics and rules are
> just not great.
>
> Another thing that's real awkard is how chaining exclusive fences
> right now means direct dma_resv.exclusive_fence pointer access with an
> rcu_assign_pointer. Not so great either.
>
> Signed-off-by: Daniel Vetter <daniel.vetter at intel.com>
> Cc: Sumit Semwal <sumit.semwal at linaro.org>
> Cc: "Christian König" <christian.koenig at amd.com>
> Cc: linux-media at vger.kernel.org
> Cc: linaro-mm-sig at lists.linaro.org
> ---
>  drivers/dma-buf/dma-resv.c |  22 ++++++--
>  include/linux/dma-resv.h   | 104 +++++++++++++++++++++++++++++++++++--
>  2 files changed, 116 insertions(+), 10 deletions(-)
>
> diff --git a/drivers/dma-buf/dma-resv.c b/drivers/dma-buf/dma-resv.c
> index f26c71747d43..898f8d894bbd 100644
> --- a/drivers/dma-buf/dma-resv.c
> +++ b/drivers/dma-buf/dma-resv.c
> @@ -48,6 +48,8 @@
>   * write operations) or N shared fences (read operations).  The RCU
>   * mechanism is used to protect read access to fences from locked
>   * write-side updates.
> + *
> + * See struct dma_resv for more details.
>   */
>
>  DEFINE_WD_CLASS(reservation_ww_class);
> @@ -137,7 +139,11 @@ EXPORT_SYMBOL(dma_resv_fini);
>   * @num_fences: number of fences we want to add
>   *
>   * Should be called before dma_resv_add_shared_fence().  Must
> - * be called with obj->lock held.
> + * be called with @obj locked through dma_resv_lock().
> + *
> + * Note that the preallocated slots need to be re-reserved if @obj is unlocked
> + * at any time before callind dma_resv_add_shared_fence(). This is validate when

s/callind/calling
s/validate/validated

> + * CONFIG_DEBUG_MUTEXES is enabled.
>   *
>   * RETURNS
>   * Zero for success, or -errno
> @@ -234,8 +240,10 @@ EXPORT_SYMBOL(dma_resv_reset_shared_max);
>   * @obj: the reservation object
>   * @fence: the shared fence to add
>   *
> - * Add a fence to a shared slot, obj->lock must be held, and
> + * Add a fence to a shared slot, @obj must be locked with dma_resv_lock(), and
>   * dma_resv_reserve_shared() has been called.
> + *
> + * See also &dma_resv.fence for a discussion of the semantics.
>   */
>  void dma_resv_add_shared_fence(struct dma_resv *obj, struct dma_fence *fence)
>  {
> @@ -280,7 +288,9 @@ EXPORT_SYMBOL(dma_resv_add_shared_fence);
>   * @obj: the reservation object
>   * @fence: the shared fence to add

"the exclusive fence", or perhaps "the fence to add to the exclusive slot"?

>   *
> - * Add a fence to the exclusive slot.  The obj->lock must be held.
> + * Add a fence to the exclusive slot. @obj must be locked with dma_resv_lock().
> + * Note that this function replaces all fences attached to @obj, see also
> + * &dma_resv.fence_excl for a discussion of the semantics.
>   */
>  void dma_resv_add_excl_fence(struct dma_resv *obj, struct dma_fence *fence)
>  {
> @@ -609,9 +619,11 @@ static inline int dma_resv_test_signaled_single(struct dma_fence *passed_fence)
>   * fence
>   *
>   * Callers are not required to hold specific locks, but maybe hold
> - * dma_resv_lock() already
> + * dma_resv_lock() already.
> + *
>   * RETURNS
> - * true if all fences signaled, else false
> + *
> + * True if all fences signaled, else false.
>   */
>  bool dma_resv_test_signaled(struct dma_resv *obj, bool test_all)
>  {
> diff --git a/include/linux/dma-resv.h b/include/linux/dma-resv.h
> index e1ca2080a1ff..c77fd54d033f 100644
> --- a/include/linux/dma-resv.h
> +++ b/include/linux/dma-resv.h
> @@ -62,16 +62,90 @@ struct dma_resv_list {
>
>  /**
>   * struct dma_resv - a reservation object manages fences for a buffer
> - * @lock: update side lock
> - * @seq: sequence count for managing RCU read-side synchronization
> - * @fence_excl: the exclusive fence, if there is one currently
> - * @fence: list of current shared fences
> + *
> + * There are multiple uses for this, with sometimes slightly different rules in
> + * how the fence slots are used.
> + *
> + * One use is to synchronize cross-driver access to a struct dma_buf, either for
> + * dynamic buffer management or just to handle implicit synchronization between
> + * different users of the buffer in userspace. See &dma_buf.resv for a more
> + * in-depth discussion.
> + *
> + * The other major use is to manage access and locking within a driver in a
> + * buffer based memory manager. struct ttm_buffer_object is the canonical
> + * example here, since this is were reservation objects originated from. But use

s/were/where

> + * in drivers is spreading and some drivers also manage struct
> + * drm_gem_object with the same scheme.
>   */
>  struct dma_resv {
> +       /**
> +        * @lock:
> +        *
> +        * Update side lock. Don't use directly, instead use the wrapper
> +        * functions like dma_resv_lock() and dma_resv_unlock().
> +        *
> +        * Drivers which use the reservation object to manage memory dynamically
> +        * also use this lock to protect buffer object state like placement,
> +        * allocation policies or throughout command submission.
> +        */
>         struct ww_mutex lock;
> +
> +       /**
> +        * @seq:
> +        *
> +        * Sequence count for managing RCU read-side synchronization, allows
> +        * read-only access to @fence_excl and @fence while ensuring we take a
> +        * consistent snapshot.
> +        */
>         seqcount_ww_mutex_t seq;
>
> +       /**
> +        * @fence_excl:
> +        *
> +        * The exclusive fence, if there is one currently.
> +        *
> +        * There are two was to update this fence:

s/was/ways

> +        *
> +        * - First by calling dma_resv_add_excl_fence(), which replaces all
> +        *   fences attached to the reservation object. To guarantee that no
> +        *   fences are lost this new fence must signal only after all previous
> +        *   fences, both shared and exclusive, have signalled. In some cases it/

Random slash at the end

> +        *   is convenient to achieve that by attaching a struct dma_fence_array
> +        *   with all the new and old fences.
> +        *
> +        * - Alternatively the fence can be set directly, which leaves the
> +        *   shared fences unchanged. To guarantee that no fences are lost this
> +        *   new fence must signale only after the previous exclusive fence has

s/signale/signal

> +        *   singalled. Since the shared fences are staying intact, it is not

s/singalled/signalled

> +        *   necessary to maintain any ordering against those. If semantically
> +        *   only a new access is added without actually treating the previous
> +        *   one as a dependency the exclusive fences can be strung together
> +        *   using struct dma_fence_chain.
> +        *
> +        * Note that actual semantics of what an exclusive or shared fence mean
> +        * is defined by the user, for reservation objects shared across drivers
> +        * see &dma_buf.resv.
> +        */
>         struct dma_fence __rcu *fence_excl;
> +
> +       /**
> +        * @fence:
> +        *
> +        * List of current shared fences.
> +        *
> +        * There are no ordering constraints of shared fences against the
> +        * exclusive fence slot. If a waiter needs to wait for all access, it
> +        * has to wait for both set of fences to signal.
> +        *
> +        * A new fence is added by calling dma_resv_add_shared_fence(). Since
> +        * this often needs to be done past the point of no return in command
> +        * submission it cannot fail, and therefor sufficient slots need to be

s/therefor/therefore

> +        * reserved by calling dma_resv_reserve_shared().
> +        *
> +        * Note that actual semantics of what an exclusive or shared fence mean
> +        * is defined by the user, for reservation objects shared across drivers
> +        * see &dma_buf.resv.
> +        */
>         struct dma_resv_list __rcu *fence;
>  };
>
> @@ -98,6 +172,13 @@ static inline void dma_resv_reset_shared_max(struct dma_resv *obj) {}
>   * undefined order, a #ww_acquire_ctx is passed to unwind if a cycle
>   * is detected. See ww_mutex_lock() and ww_acquire_init(). A reservation
>   * object may be locked by itself by passing NULL as @ctx.
> + *
> + * When a die situation is indicated by returning -EDEADLK all locks held by
> + * @ctx must be unlocked and then dma_resv_lock_slow() called on @obj.
> + *
> + * Unlocked by calling dma_resv_lock().

dma_resv_unlock()

> + *
> + * See also dma_resv_lock_interruptible() for the interruptible variant.
>   */
>  static inline int dma_resv_lock(struct dma_resv *obj,
>                                 struct ww_acquire_ctx *ctx)
> @@ -119,6 +200,12 @@ static inline int dma_resv_lock(struct dma_resv *obj,
>   * undefined order, a #ww_acquire_ctx is passed to unwind if a cycle
>   * is detected. See ww_mutex_lock() and ww_acquire_init(). A reservation
>   * object may be locked by itself by passing NULL as @ctx.
> + *
> + * When a die situation is indicated by returning -EDEADLK all locks held by
> + * @ctx must be unlocked and then dma_resv_lock_slow_interruptible() called on
> + * @obj.
> + *
> + * Unlocked by calling dma_resv_lock().

dma_resv_unlock()

fwiw,
Reviewed-by: Matthew Auld <matthew.auld at intel.com>


>   */
>  static inline int dma_resv_lock_interruptible(struct dma_resv *obj,
>                                               struct ww_acquire_ctx *ctx)
> @@ -134,6 +221,8 @@ static inline int dma_resv_lock_interruptible(struct dma_resv *obj,
>   * Acquires the reservation object after a die case. This function
>   * will sleep until the lock becomes available. See dma_resv_lock() as
>   * well.
> + *
> + * See also dma_resv_lock_slow_interruptible() for the interruptible variant.
>   */
>  static inline void dma_resv_lock_slow(struct dma_resv *obj,
>                                       struct ww_acquire_ctx *ctx)
> @@ -167,7 +256,7 @@ static inline int dma_resv_lock_slow_interruptible(struct dma_resv *obj,
>   * if they overlap with a writer.
>   *
>   * Also note that since no context is provided, no deadlock protection is
> - * possible.
> + * possible, which is also not needed for a trylock.
>   *
>   * Returns true if the lock was acquired, false otherwise.
>   */
> @@ -193,6 +282,11 @@ static inline bool dma_resv_is_locked(struct dma_resv *obj)
>   *
>   * Returns the context used to lock a reservation object or NULL if no context
>   * was used or the object is not locked at all.
> + *
> + * WARNING: This interface is pretty horrible, but TTM needs it because it
> + * doesn't pass the struct ww_acquire_ctx around in some very long callchains.
> + * Everyone else just uses it to check whether they're holding a reservation or
> + * not.
>   */
>  static inline struct ww_acquire_ctx *dma_resv_locking_ctx(struct dma_resv *obj)
>  {
> --
> 2.32.0
>
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