drivers/gpu/drm/i915/i915_active.h - linux/torvalds/linux - Git at Google

 /*
  * SPDX-License-Identifier: MIT
  *
  * Copyright © 2019 Intel Corporation
  */

 #ifndef _I915_ACTIVE_H_
 #define _I915_ACTIVE_H_

 #include <linux/lockdep.h>

 #include "i915_active_types.h"
 #include "i915_request.h"

 /*
  * We treat requests as fences. This is not be to confused with our
  * "fence registers" but pipeline synchronisation objects ala GL_ARB_sync.
  * We use the fences to synchronize access from the CPU with activity on the
  * GPU, for example, we should not rewrite an object's PTE whilst the GPU
  * is reading them. We also track fences at a higher level to provide
  * implicit synchronisation around GEM objects, e.g. set-domain will wait
  * for outstanding GPU rendering before marking the object ready for CPU
  * access, or a pageflip will wait until the GPU is complete before showing
  * the frame on the scanout.
  *
  * In order to use a fence, the object must track the fence it needs to
  * serialise with. For example, GEM objects want to track both read and
  * write access so that we can perform concurrent read operations between
  * the CPU and GPU engines, as well as waiting for all rendering to
  * complete, or waiting for the last GPU user of a "fence register". The
  * object then embeds a #i915_active_request to track the most recent (in
  * retirement order) request relevant for the desired mode of access.
  * The #i915_active_request is updated with i915_active_request_set() to
  * track the most recent fence request, typically this is done as part of
  * i915_vma_move_to_active().
  *
  * When the #i915_active_request completes (is retired), it will
  * signal its completion to the owner through a callback as well as mark
  * itself as idle (i915_active_request.request == NULL). The owner
  * can then perform any action, such as delayed freeing of an active
  * resource including itself.
  */

 void i915_active_retire_noop(struct i915_active_request *active,
 			     struct i915_request *request);

 /**
  * i915_active_request_init - prepares the activity tracker for use
  * @active - the active tracker
  * @rq - initial request to track, can be NULL
  * @func - a callback when then the tracker is retired (becomes idle),
  *         can be NULL
  *
  * i915_active_request_init() prepares the embedded @active struct for use as
  * an activity tracker, that is for tracking the last known active request
  * associated with it. When the last request becomes idle, when it is retired
  * after completion, the optional callback @func is invoked.
  */
 static inline void
 i915_active_request_init(struct i915_active_request *active,
 			 struct mutex *lock,
 			 struct i915_request *rq,
 			 i915_active_retire_fn retire)
 {
 	RCU_INIT_POINTER(active->request, rq);
 	INIT_LIST_HEAD(&active->link);
 	active->retire = retire ?: i915_active_retire_noop;
 #if IS_ENABLED(CONFIG_DRM_I915_DEBUG_GEM)
 	active->lock = lock;
 #endif
 }

 #define INIT_ACTIVE_REQUEST(name, lock) \
 	i915_active_request_init((name), (lock), NULL, NULL)

 /**
  * i915_active_request_set - updates the tracker to watch the current request
  * @active - the active tracker
  * @request - the request to watch
  *
  * __i915_active_request_set() watches the given @request for completion. Whilst
  * that @request is busy, the @active reports busy. When that @request is
  * retired, the @active tracker is updated to report idle.
  */
 static inline void
 __i915_active_request_set(struct i915_active_request *active,
 			  struct i915_request *request)
 {
 #if IS_ENABLED(CONFIG_DRM_I915_DEBUG_GEM)
 	lockdep_assert_held(active->lock);
 #endif
 	list_move(&active->link, &request->active_list);
 	rcu_assign_pointer(active->request, request);
 }

 int __must_check
 i915_active_request_set(struct i915_active_request *active,
 			struct i915_request *rq);

 /**
  * i915_active_request_raw - return the active request
  * @active - the active tracker
  *
  * i915_active_request_raw() returns the current request being tracked, or NULL.
  * It does not obtain a reference on the request for the caller, so the caller
  * must hold struct_mutex.
  */
 static inline struct i915_request *
 i915_active_request_raw(const struct i915_active_request *active,
 			struct mutex *mutex)
 {
 	return rcu_dereference_protected(active->request,
 					 lockdep_is_held(mutex));
 }

 /**
  * i915_active_request_peek - report the active request being monitored
  * @active - the active tracker
  *
  * i915_active_request_peek() returns the current request being tracked if
  * still active, or NULL. It does not obtain a reference on the request
  * for the caller, so the caller must hold struct_mutex.
  */
 static inline struct i915_request *
 i915_active_request_peek(const struct i915_active_request *active,
 			 struct mutex *mutex)
 {
 	struct i915_request *request;

 	request = i915_active_request_raw(active, mutex);
 	if (!request || i915_request_completed(request))
 		return NULL;

 	return request;
 }

 /**
  * i915_active_request_get - return a reference to the active request
  * @active - the active tracker
  *
  * i915_active_request_get() returns a reference to the active request, or NULL
  * if the active tracker is idle. The caller must hold struct_mutex.
  */
 static inline struct i915_request *
 i915_active_request_get(const struct i915_active_request *active,
 			struct mutex *mutex)
 {
 	return i915_request_get(i915_active_request_peek(active, mutex));
 }

 /**
  * __i915_active_request_get_rcu - return a reference to the active request
  * @active - the active tracker
  *
  * __i915_active_request_get() returns a reference to the active request,
  * or NULL if the active tracker is idle. The caller must hold the RCU read
  * lock, but the returned pointer is safe to use outside of RCU.
  */
 static inline struct i915_request *
 __i915_active_request_get_rcu(const struct i915_active_request *active)
 {
 	/*
 	 * Performing a lockless retrieval of the active request is super
 	 * tricky. SLAB_TYPESAFE_BY_RCU merely guarantees that the backing
 	 * slab of request objects will not be freed whilst we hold the
 	 * RCU read lock. It does not guarantee that the request itself
 	 * will not be freed and then *reused*. Viz,
 	 *
 	 * Thread A			Thread B
 	 *
 	 * rq = active.request
 	 *				retire(rq) -> free(rq);
 	 *				(rq is now first on the slab freelist)
 	 *				active.request = NULL
 	 *
 	 *				rq = new submission on a new object
 	 * ref(rq)
 	 *
 	 * To prevent the request from being reused whilst the caller
 	 * uses it, we take a reference like normal. Whilst acquiring
 	 * the reference we check that it is not in a destroyed state
 	 * (refcnt == 0). That prevents the request being reallocated
 	 * whilst the caller holds on to it. To check that the request
 	 * was not reallocated as we acquired the reference we have to
 	 * check that our request remains the active request across
 	 * the lookup, in the same manner as a seqlock. The visibility
 	 * of the pointer versus the reference counting is controlled
 	 * by using RCU barriers (rcu_dereference and rcu_assign_pointer).
 	 *
 	 * In the middle of all that, we inspect whether the request is
 	 * complete. Retiring is lazy so the request may be completed long
 	 * before the active tracker is updated. Querying whether the
 	 * request is complete is far cheaper (as it involves no locked
 	 * instructions setting cachelines to exclusive) than acquiring
 	 * the reference, so we do it first. The RCU read lock ensures the
 	 * pointer dereference is valid, but does not ensure that the
 	 * seqno nor HWS is the right one! However, if the request was
 	 * reallocated, that means the active tracker's request was complete.
 	 * If the new request is also complete, then both are and we can
 	 * just report the active tracker is idle. If the new request is
 	 * incomplete, then we acquire a reference on it and check that
 	 * it remained the active request.
 	 *
 	 * It is then imperative that we do not zero the request on
 	 * reallocation, so that we can chase the dangling pointers!
 	 * See i915_request_alloc().
 	 */
 	do {
 		struct i915_request *request;

 		request = rcu_dereference(active->request);
 		if (!request || i915_request_completed(request))
 			return NULL;

 		/*
 		 * An especially silly compiler could decide to recompute the
 		 * result of i915_request_completed, more specifically
 		 * re-emit the load for request->fence.seqno. A race would catch
 		 * a later seqno value, which could flip the result from true to
 		 * false. Which means part of the instructions below might not
 		 * be executed, while later on instructions are executed. Due to
 		 * barriers within the refcounting the inconsistency can't reach
 		 * past the call to i915_request_get_rcu, but not executing
 		 * that while still executing i915_request_put() creates
 		 * havoc enough.  Prevent this with a compiler barrier.
 		 */
 		barrier();

 		request = i915_request_get_rcu(request);

 		/*
 		 * What stops the following rcu_access_pointer() from occurring
 		 * before the above i915_request_get_rcu()? If we were
 		 * to read the value before pausing to get the reference to
 		 * the request, we may not notice a change in the active
 		 * tracker.
 		 *
 		 * The rcu_access_pointer() is a mere compiler barrier, which
 		 * means both the CPU and compiler are free to perform the
 		 * memory read without constraint. The compiler only has to
 		 * ensure that any operations after the rcu_access_pointer()
 		 * occur afterwards in program order. This means the read may
 		 * be performed earlier by an out-of-order CPU, or adventurous
 		 * compiler.
 		 *
 		 * The atomic operation at the heart of
 		 * i915_request_get_rcu(), see dma_fence_get_rcu(), is
 		 * atomic_inc_not_zero() which is only a full memory barrier
 		 * when successful. That is, if i915_request_get_rcu()
 		 * returns the request (and so with the reference counted
 		 * incremented) then the following read for rcu_access_pointer()
 		 * must occur after the atomic operation and so confirm
 		 * that this request is the one currently being tracked.
 		 *
 		 * The corresponding write barrier is part of
 		 * rcu_assign_pointer().
 		 */
 		if (!request || request == rcu_access_pointer(active->request))
 			return rcu_pointer_handoff(request);

 		i915_request_put(request);
 	} while (1);
 }

 /**
  * i915_active_request_get_unlocked - return a reference to the active request
  * @active - the active tracker
  *
  * i915_active_request_get_unlocked() returns a reference to the active request,
  * or NULL if the active tracker is idle. The reference is obtained under RCU,
  * so no locking is required by the caller.
  *
  * The reference should be freed with i915_request_put().
  */
 static inline struct i915_request *
 i915_active_request_get_unlocked(const struct i915_active_request *active)
 {
 	struct i915_request *request;

 	rcu_read_lock();
 	request = __i915_active_request_get_rcu(active);
 	rcu_read_unlock();

 	return request;
 }

 /**
  * i915_active_request_isset - report whether the active tracker is assigned
  * @active - the active tracker
  *
  * i915_active_request_isset() returns true if the active tracker is currently
  * assigned to a request. Due to the lazy retiring, that request may be idle
  * and this may report stale information.
  */
 static inline bool
 i915_active_request_isset(const struct i915_active_request *active)
 {
 	return rcu_access_pointer(active->request);
 }

 /**
  * i915_active_request_retire - waits until the request is retired
  * @active - the active request on which to wait
  *
  * i915_active_request_retire() waits until the request is completed,
  * and then ensures that at least the retirement handler for this
  * @active tracker is called before returning. If the @active
  * tracker is idle, the function returns immediately.
  */
 static inline int __must_check
 i915_active_request_retire(struct i915_active_request *active,
 			   struct mutex *mutex)
 {
 	struct i915_request *request;
 	long ret;

 	request = i915_active_request_raw(active, mutex);
 	if (!request)
 		return 0;

 	ret = i915_request_wait(request,
 				I915_WAIT_INTERRUPTIBLE,
 				MAX_SCHEDULE_TIMEOUT);
 	if (ret < 0)
 		return ret;

 	list_del_init(&active->link);
 	RCU_INIT_POINTER(active->request, NULL);

 	active->retire(active, request);

 	return 0;
 }

 /*
  * GPU activity tracking
  *
  * Each set of commands submitted to the GPU compromises a single request that
  * signals a fence upon completion. struct i915_request combines the
  * command submission, scheduling and fence signaling roles. If we want to see
  * if a particular task is complete, we need to grab the fence (struct
  * i915_request) for that task and check or wait for it to be signaled. More
  * often though we want to track the status of a bunch of tasks, for example
  * to wait for the GPU to finish accessing some memory across a variety of
  * different command pipelines from different clients. We could choose to
  * track every single request associated with the task, but knowing that
  * each request belongs to an ordered timeline (later requests within a
  * timeline must wait for earlier requests), we need only track the
  * latest request in each timeline to determine the overall status of the
  * task.
  *
  * struct i915_active provides this tracking across timelines. It builds a
  * composite shared-fence, and is updated as new work is submitted to the task,
  * forming a snapshot of the current status. It should be embedded into the
  * different resources that need to track their associated GPU activity to
  * provide a callback when that GPU activity has ceased, or otherwise to
  * provide a serialisation point either for request submission or for CPU
  * synchronisation.
  */

 void __i915_active_init(struct drm_i915_private *i915,
 			struct i915_active *ref,
 			int (*active)(struct i915_active *ref),
 			void (*retire)(struct i915_active *ref),
 			struct lock_class_key *key);
 #define i915_active_init(i915, ref, active, retire) do {		\
 	static struct lock_class_key __key;				\
 									\
 	__i915_active_init(i915, ref, active, retire, &__key);		\
 } while (0)

 int i915_active_ref(struct i915_active *ref,
 		    struct intel_timeline *tl,
 		    struct i915_request *rq);

 int i915_active_wait(struct i915_active *ref);

 int i915_request_await_active(struct i915_request *rq,
 			      struct i915_active *ref);
 int i915_request_await_active_request(struct i915_request *rq,
 				      struct i915_active_request *active);

 int i915_active_acquire(struct i915_active *ref);
 void i915_active_release(struct i915_active *ref);
 void __i915_active_release_nested(struct i915_active *ref, int subclass);

 bool i915_active_trygrab(struct i915_active *ref);
 void i915_active_ungrab(struct i915_active *ref);

 static inline bool
 i915_active_is_idle(const struct i915_active *ref)
 {
 	return !atomic_read(&ref->count);
 }

 #if IS_ENABLED(CONFIG_DRM_I915_DEBUG_GEM)
 void i915_active_fini(struct i915_active *ref);
 #else
 static inline void i915_active_fini(struct i915_active *ref) { }
 #endif

 int i915_active_acquire_preallocate_barrier(struct i915_active *ref,
 					    struct intel_engine_cs *engine);
 void i915_active_acquire_barrier(struct i915_active *ref);
 void i915_request_add_active_barriers(struct i915_request *rq);

 #endif /* _I915_ACTIVE_H_ */
	/*
	* SPDX-License-Identifier: MIT
	*
	* Copyright © 2019 Intel Corporation
	*/

	#ifndef _I915_ACTIVE_H_
	#define _I915_ACTIVE_H_

	#include <linux/lockdep.h>

	#include "i915_active_types.h"
	#include "i915_request.h"

	/*
	* We treat requests as fences. This is not be to confused with our
	* "fence registers" but pipeline synchronisation objects ala GL_ARB_sync.
	* We use the fences to synchronize access from the CPU with activity on the
	* GPU, for example, we should not rewrite an object's PTE whilst the GPU
	* is reading them. We also track fences at a higher level to provide
	* implicit synchronisation around GEM objects, e.g. set-domain will wait
	* for outstanding GPU rendering before marking the object ready for CPU
	* access, or a pageflip will wait until the GPU is complete before showing
	* the frame on the scanout.
	*
	* In order to use a fence, the object must track the fence it needs to
	* serialise with. For example, GEM objects want to track both read and
	* write access so that we can perform concurrent read operations between
	* the CPU and GPU engines, as well as waiting for all rendering to
	* complete, or waiting for the last GPU user of a "fence register". The
	* object then embeds a #i915_active_request to track the most recent (in
	* retirement order) request relevant for the desired mode of access.
	* The #i915_active_request is updated with i915_active_request_set() to
	* track the most recent fence request, typically this is done as part of
	* i915_vma_move_to_active().
	*
	* When the #i915_active_request completes (is retired), it will
	* signal its completion to the owner through a callback as well as mark
	* itself as idle (i915_active_request.request == NULL). The owner
	* can then perform any action, such as delayed freeing of an active
	* resource including itself.
	*/

	void i915_active_retire_noop(struct i915_active_request *active,
	struct i915_request *request);

	/**
	* i915_active_request_init - prepares the activity tracker for use
	* @active - the active tracker
	* @rq - initial request to track, can be NULL
	* @func - a callback when then the tracker is retired (becomes idle),
	* can be NULL
	*
	* i915_active_request_init() prepares the embedded @active struct for use as
	* an activity tracker, that is for tracking the last known active request
	* associated with it. When the last request becomes idle, when it is retired
	* after completion, the optional callback @func is invoked.
	*/
	static inline void
	i915_active_request_init(struct i915_active_request *active,
	struct mutex *lock,
	struct i915_request *rq,
	i915_active_retire_fn retire)
	{
	RCU_INIT_POINTER(active->request, rq);
	INIT_LIST_HEAD(&active->link);
	active->retire = retire ?: i915_active_retire_noop;
	#if IS_ENABLED(CONFIG_DRM_I915_DEBUG_GEM)
	active->lock = lock;
	#endif
	}

	#define INIT_ACTIVE_REQUEST(name, lock) \
	i915_active_request_init((name), (lock), NULL, NULL)

	/**
	* i915_active_request_set - updates the tracker to watch the current request
	* @active - the active tracker
	* @request - the request to watch
	*
	* __i915_active_request_set() watches the given @request for completion. Whilst
	* that @request is busy, the @active reports busy. When that @request is
	* retired, the @active tracker is updated to report idle.
	*/
	static inline void
	__i915_active_request_set(struct i915_active_request *active,
	struct i915_request *request)
	{
	#if IS_ENABLED(CONFIG_DRM_I915_DEBUG_GEM)
	lockdep_assert_held(active->lock);
	#endif
	list_move(&active->link, &request->active_list);
	rcu_assign_pointer(active->request, request);
	}

	int __must_check
	i915_active_request_set(struct i915_active_request *active,
	struct i915_request *rq);

	/**
	* i915_active_request_raw - return the active request
	* @active - the active tracker
	*
	* i915_active_request_raw() returns the current request being tracked, or NULL.
	* It does not obtain a reference on the request for the caller, so the caller
	* must hold struct_mutex.
	*/
	static inline struct i915_request *
	i915_active_request_raw(const struct i915_active_request *active,
	struct mutex *mutex)
	{
	return rcu_dereference_protected(active->request,
	lockdep_is_held(mutex));
	}

	/**
	* i915_active_request_peek - report the active request being monitored
	* @active - the active tracker
	*
	* i915_active_request_peek() returns the current request being tracked if
	* still active, or NULL. It does not obtain a reference on the request
	* for the caller, so the caller must hold struct_mutex.
	*/
	static inline struct i915_request *
	i915_active_request_peek(const struct i915_active_request *active,
	struct mutex *mutex)
	{
	struct i915_request *request;

	request = i915_active_request_raw(active, mutex);
	if (!request \|\| i915_request_completed(request))
	return NULL;

	return request;
	}

	/**
	* i915_active_request_get - return a reference to the active request
	* @active - the active tracker
	*
	* i915_active_request_get() returns a reference to the active request, or NULL
	* if the active tracker is idle. The caller must hold struct_mutex.
	*/
	static inline struct i915_request *
	i915_active_request_get(const struct i915_active_request *active,
	struct mutex *mutex)
	{
	return i915_request_get(i915_active_request_peek(active, mutex));
	}

	/**
	* __i915_active_request_get_rcu - return a reference to the active request
	* @active - the active tracker
	*
	* __i915_active_request_get() returns a reference to the active request,
	* or NULL if the active tracker is idle. The caller must hold the RCU read
	* lock, but the returned pointer is safe to use outside of RCU.
	*/
	static inline struct i915_request *
	__i915_active_request_get_rcu(const struct i915_active_request *active)
	{
	/*
	* Performing a lockless retrieval of the active request is super
	* tricky. SLAB_TYPESAFE_BY_RCU merely guarantees that the backing
	* slab of request objects will not be freed whilst we hold the
	* RCU read lock. It does not guarantee that the request itself
	* will not be freed and then reused. Viz,
	*
	* Thread A Thread B
	*
	* rq = active.request
	* retire(rq) -> free(rq);
	* (rq is now first on the slab freelist)
	* active.request = NULL
	*
	* rq = new submission on a new object
	* ref(rq)
	*
	* To prevent the request from being reused whilst the caller
	* uses it, we take a reference like normal. Whilst acquiring
	* the reference we check that it is not in a destroyed state
	* (refcnt == 0). That prevents the request being reallocated
	* whilst the caller holds on to it. To check that the request
	* was not reallocated as we acquired the reference we have to
	* check that our request remains the active request across
	* the lookup, in the same manner as a seqlock. The visibility
	* of the pointer versus the reference counting is controlled
	* by using RCU barriers (rcu_dereference and rcu_assign_pointer).
	*
	* In the middle of all that, we inspect whether the request is
	* complete. Retiring is lazy so the request may be completed long
	* before the active tracker is updated. Querying whether the
	* request is complete is far cheaper (as it involves no locked
	* instructions setting cachelines to exclusive) than acquiring
	* the reference, so we do it first. The RCU read lock ensures the
	* pointer dereference is valid, but does not ensure that the
	* seqno nor HWS is the right one! However, if the request was
	* reallocated, that means the active tracker's request was complete.
	* If the new request is also complete, then both are and we can
	* just report the active tracker is idle. If the new request is
	* incomplete, then we acquire a reference on it and check that
	* it remained the active request.
	*
	* It is then imperative that we do not zero the request on
	* reallocation, so that we can chase the dangling pointers!
	* See i915_request_alloc().
	*/
	do {
	struct i915_request *request;

	request = rcu_dereference(active->request);
	if (!request \|\| i915_request_completed(request))
	return NULL;

	/*
	* An especially silly compiler could decide to recompute the
	* result of i915_request_completed, more specifically
	* re-emit the load for request->fence.seqno. A race would catch
	* a later seqno value, which could flip the result from true to
	* false. Which means part of the instructions below might not
	* be executed, while later on instructions are executed. Due to
	* barriers within the refcounting the inconsistency can't reach
	* past the call to i915_request_get_rcu, but not executing
	* that while still executing i915_request_put() creates
	* havoc enough. Prevent this with a compiler barrier.
	*/
	barrier();

	request = i915_request_get_rcu(request);

	/*
	* What stops the following rcu_access_pointer() from occurring
	* before the above i915_request_get_rcu()? If we were
	* to read the value before pausing to get the reference to
	* the request, we may not notice a change in the active
	* tracker.
	*
	* The rcu_access_pointer() is a mere compiler barrier, which
	* means both the CPU and compiler are free to perform the
	* memory read without constraint. The compiler only has to
	* ensure that any operations after the rcu_access_pointer()
	* occur afterwards in program order. This means the read may
	* be performed earlier by an out-of-order CPU, or adventurous
	* compiler.
	*
	* The atomic operation at the heart of
	* i915_request_get_rcu(), see dma_fence_get_rcu(), is
	* atomic_inc_not_zero() which is only a full memory barrier
	* when successful. That is, if i915_request_get_rcu()
	* returns the request (and so with the reference counted
	* incremented) then the following read for rcu_access_pointer()
	* must occur after the atomic operation and so confirm
	* that this request is the one currently being tracked.
	*
	* The corresponding write barrier is part of
	* rcu_assign_pointer().
	*/
	if (!request \|\| request == rcu_access_pointer(active->request))
	return rcu_pointer_handoff(request);

	i915_request_put(request);
	} while (1);
	}

	/**
	* i915_active_request_get_unlocked - return a reference to the active request
	* @active - the active tracker
	*
	* i915_active_request_get_unlocked() returns a reference to the active request,
	* or NULL if the active tracker is idle. The reference is obtained under RCU,
	* so no locking is required by the caller.
	*
	* The reference should be freed with i915_request_put().
	*/
	static inline struct i915_request *
	i915_active_request_get_unlocked(const struct i915_active_request *active)
	{
	struct i915_request *request;

	rcu_read_lock();
	request = __i915_active_request_get_rcu(active);
	rcu_read_unlock();

	return request;
	}

	/**
	* i915_active_request_isset - report whether the active tracker is assigned
	* @active - the active tracker
	*
	* i915_active_request_isset() returns true if the active tracker is currently
	* assigned to a request. Due to the lazy retiring, that request may be idle
	* and this may report stale information.
	*/
	static inline bool
	i915_active_request_isset(const struct i915_active_request *active)
	{
	return rcu_access_pointer(active->request);
	}

	/**
	* i915_active_request_retire - waits until the request is retired
	* @active - the active request on which to wait
	*
	* i915_active_request_retire() waits until the request is completed,
	* and then ensures that at least the retirement handler for this
	* @active tracker is called before returning. If the @active
	* tracker is idle, the function returns immediately.
	*/
	static inline int __must_check
	i915_active_request_retire(struct i915_active_request *active,
	struct mutex *mutex)
	{
	struct i915_request *request;
	long ret;

	request = i915_active_request_raw(active, mutex);
	if (!request)
	return 0;

	ret = i915_request_wait(request,
	I915_WAIT_INTERRUPTIBLE,
	MAX_SCHEDULE_TIMEOUT);
	if (ret < 0)
	return ret;

	list_del_init(&active->link);
	RCU_INIT_POINTER(active->request, NULL);

	active->retire(active, request);

	return 0;
	}

	/*
	* GPU activity tracking
	*
	* Each set of commands submitted to the GPU compromises a single request that
	* signals a fence upon completion. struct i915_request combines the
	* command submission, scheduling and fence signaling roles. If we want to see
	* if a particular task is complete, we need to grab the fence (struct
	* i915_request) for that task and check or wait for it to be signaled. More
	* often though we want to track the status of a bunch of tasks, for example
	* to wait for the GPU to finish accessing some memory across a variety of
	* different command pipelines from different clients. We could choose to
	* track every single request associated with the task, but knowing that
	* each request belongs to an ordered timeline (later requests within a
	* timeline must wait for earlier requests), we need only track the
	* latest request in each timeline to determine the overall status of the
	* task.
	*
	* struct i915_active provides this tracking across timelines. It builds a
	* composite shared-fence, and is updated as new work is submitted to the task,
	* forming a snapshot of the current status. It should be embedded into the
	* different resources that need to track their associated GPU activity to
	* provide a callback when that GPU activity has ceased, or otherwise to
	* provide a serialisation point either for request submission or for CPU
	* synchronisation.
	*/

	void __i915_active_init(struct drm_i915_private *i915,
	struct i915_active *ref,
	int (active)(struct i915_active ref),
	void (retire)(struct i915_active ref),
	struct lock_class_key *key);
	#define i915_active_init(i915, ref, active, retire) do { \
	static struct lock_class_key __key; \
	\
	__i915_active_init(i915, ref, active, retire, &__key); \
	} while (0)

	int i915_active_ref(struct i915_active *ref,
	struct intel_timeline *tl,
	struct i915_request *rq);

	int i915_active_wait(struct i915_active *ref);

	int i915_request_await_active(struct i915_request *rq,
	struct i915_active *ref);
	int i915_request_await_active_request(struct i915_request *rq,
	struct i915_active_request *active);

	int i915_active_acquire(struct i915_active *ref);
	void i915_active_release(struct i915_active *ref);
	void __i915_active_release_nested(struct i915_active *ref, int subclass);

	bool i915_active_trygrab(struct i915_active *ref);
	void i915_active_ungrab(struct i915_active *ref);

	static inline bool
	i915_active_is_idle(const struct i915_active *ref)
	{
	return !atomic_read(&ref->count);
	}

	#if IS_ENABLED(CONFIG_DRM_I915_DEBUG_GEM)
	void i915_active_fini(struct i915_active *ref);
	#else
	static inline void i915_active_fini(struct i915_active *ref) { }
	#endif

	int i915_active_acquire_preallocate_barrier(struct i915_active *ref,
	struct intel_engine_cs *engine);
	void i915_active_acquire_barrier(struct i915_active *ref);
	void i915_request_add_active_barriers(struct i915_request *rq);

	#endif /* _I915_ACTIVE_H_ */