linux/drivers/gpu/drm/i915/i915_gem_request.h
Chris Wilson 6c067579e6 drm/i915: Split execlist priority queue into rbtree + linked list
All the requests at the same priority are executed in FIFO order. They
do not need to be stored in the rbtree themselves, as they are a simple
list within a level. If we move the requests at one priority into a list,
we can then reduce the rbtree to the set of priorities. This should keep
the height of the rbtree small, as the number of active priorities can not
exceed the number of active requests and should be typically only a few.

Currently, we have ~2k possible different priority levels, that may
increase to allow even more fine grained selection. Allocating those in
advance seems a waste (and may be impossible), so we opt for allocating
upon first use, and freeing after its requests are depleted. To avoid
the possibility of an allocation failure causing us to lose a request,
we preallocate the default priority (0) and bump any request to that
priority if we fail to allocate it the appropriate plist. Having a
request (that is ready to run, so not leading to corruption) execute
out-of-order is better than leaking the request (and its dependency
tree) entirely.

There should be a benefit to reducing execlists_dequeue() to principally
using a simple list (and reducing the frequency of both rbtree iteration
and balancing on erase) but for typical workloads, request coalescing
should be small enough that we don't notice any change. The main gain is
from improving PI calls to schedule, and the explicit list within a
level should make request unwinding simpler (we just need to insert at
the head of the list rather than the tail and not have to make the
rbtree search more complicated).

v2: Avoid use-after-free when deleting a depleted priolist

v3: Michał found the solution to handling the allocation failure
gracefully. If we disable all priority scheduling following the
allocation failure, those requests will be executed in fifo and we will
ensure that this request and its dependencies are in strict fifo (even
when it doesn't realise it is only a single list). Normal scheduling is
restored once we know the device is idle, until the next failure!
Suggested-by: Michał Wajdeczko <michal.wajdeczko@intel.com>

Signed-off-by: Chris Wilson <chris@chris-wilson.co.uk>
Cc: Michał Winiarski <michal.winiarski@intel.com>
Cc: Tvrtko Ursulin <tvrtko.ursulin@intel.com>
Cc: Joonas Lahtinen <joonas.lahtinen@linux.intel.com>
Reviewed-by: Michał Winiarski <michal.winiarski@intel.com>
Reviewed-by: Tvrtko Ursulin <tvrtko.ursulin@intel.com>
Link: http://patchwork.freedesktop.org/patch/msgid/20170517121007.27224-8-chris@chris-wilson.co.uk
2017-05-17 13:38:09 +01:00

746 lines
26 KiB
C

/*
* Copyright © 2008-2015 Intel Corporation
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice (including the next
* paragraph) shall be included in all copies or substantial portions of the
* Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
* IN THE SOFTWARE.
*
*/
#ifndef I915_GEM_REQUEST_H
#define I915_GEM_REQUEST_H
#include <linux/dma-fence.h>
#include "i915_gem.h"
#include "i915_sw_fence.h"
struct drm_file;
struct drm_i915_gem_object;
struct drm_i915_gem_request;
struct intel_wait {
struct rb_node node;
struct task_struct *tsk;
struct drm_i915_gem_request *request;
u32 seqno;
};
struct intel_signal_node {
struct rb_node node;
struct intel_wait wait;
};
struct i915_dependency {
struct i915_priotree *signaler;
struct list_head signal_link;
struct list_head wait_link;
struct list_head dfs_link;
unsigned long flags;
#define I915_DEPENDENCY_ALLOC BIT(0)
};
/* Requests exist in a complex web of interdependencies. Each request
* has to wait for some other request to complete before it is ready to be run
* (e.g. we have to wait until the pixels have been rendering into a texture
* before we can copy from it). We track the readiness of a request in terms
* of fences, but we also need to keep the dependency tree for the lifetime
* of the request (beyond the life of an individual fence). We use the tree
* at various points to reorder the requests whilst keeping the requests
* in order with respect to their various dependencies.
*/
struct i915_priotree {
struct list_head signalers_list; /* those before us, we depend upon */
struct list_head waiters_list; /* those after us, they depend upon us */
struct list_head link;
int priority;
#define I915_PRIORITY_MAX 1024
#define I915_PRIORITY_NORMAL 0
#define I915_PRIORITY_MIN (-I915_PRIORITY_MAX)
};
struct i915_gem_capture_list {
struct i915_gem_capture_list *next;
struct i915_vma *vma;
};
/**
* Request queue structure.
*
* The request queue allows us to note sequence numbers that have been emitted
* and may be associated with active buffers to be retired.
*
* By keeping this list, we can avoid having to do questionable sequence
* number comparisons on buffer last_read|write_seqno. It also allows an
* emission time to be associated with the request for tracking how far ahead
* of the GPU the submission is.
*
* When modifying this structure be very aware that we perform a lockless
* RCU lookup of it that may race against reallocation of the struct
* from the slab freelist. We intentionally do not zero the structure on
* allocation so that the lookup can use the dangling pointers (and is
* cogniscent that those pointers may be wrong). Instead, everything that
* needs to be initialised must be done so explicitly.
*
* The requests are reference counted.
*/
struct drm_i915_gem_request {
struct dma_fence fence;
spinlock_t lock;
/** On Which ring this request was generated */
struct drm_i915_private *i915;
/**
* Context and ring buffer related to this request
* Contexts are refcounted, so when this request is associated with a
* context, we must increment the context's refcount, to guarantee that
* it persists while any request is linked to it. Requests themselves
* are also refcounted, so the request will only be freed when the last
* reference to it is dismissed, and the code in
* i915_gem_request_free() will then decrement the refcount on the
* context.
*/
struct i915_gem_context *ctx;
struct intel_engine_cs *engine;
struct intel_ring *ring;
struct intel_timeline *timeline;
struct intel_signal_node signaling;
/* Fences for the various phases in the request's lifetime.
*
* The submit fence is used to await upon all of the request's
* dependencies. When it is signaled, the request is ready to run.
* It is used by the driver to then queue the request for execution.
*/
struct i915_sw_fence submit;
wait_queue_t submitq;
wait_queue_head_t execute;
/* A list of everyone we wait upon, and everyone who waits upon us.
* Even though we will not be submitted to the hardware before the
* submit fence is signaled (it waits for all external events as well
* as our own requests), the scheduler still needs to know the
* dependency tree for the lifetime of the request (from execbuf
* to retirement), i.e. bidirectional dependency information for the
* request not tied to individual fences.
*/
struct i915_priotree priotree;
struct i915_dependency dep;
/** GEM sequence number associated with this request on the
* global execution timeline. It is zero when the request is not
* on the HW queue (i.e. not on the engine timeline list).
* Its value is guarded by the timeline spinlock.
*/
u32 global_seqno;
/** Position in the ring of the start of the request */
u32 head;
/**
* Position in the ring of the start of the postfix.
* This is required to calculate the maximum available ring space
* without overwriting the postfix.
*/
u32 postfix;
/** Position in the ring of the end of the whole request */
u32 tail;
/** Position in the ring of the end of any workarounds after the tail */
u32 wa_tail;
/** Preallocate space in the ring for the emitting the request */
u32 reserved_space;
/** Batch buffer related to this request if any (used for
* error state dump only).
*/
struct i915_vma *batch;
/** Additional buffers requested by userspace to be captured upon
* a GPU hang. The vma/obj on this list are protected by their
* active reference - all objects on this list must also be
* on the active_list (of their final request).
*/
struct i915_gem_capture_list *capture_list;
struct list_head active_list;
/** Time at which this request was emitted, in jiffies. */
unsigned long emitted_jiffies;
/** engine->request_list entry for this request */
struct list_head link;
/** ring->request_list entry for this request */
struct list_head ring_link;
struct drm_i915_file_private *file_priv;
/** file_priv list entry for this request */
struct list_head client_link;
};
extern const struct dma_fence_ops i915_fence_ops;
static inline bool dma_fence_is_i915(const struct dma_fence *fence)
{
return fence->ops == &i915_fence_ops;
}
struct drm_i915_gem_request * __must_check
i915_gem_request_alloc(struct intel_engine_cs *engine,
struct i915_gem_context *ctx);
void i915_gem_request_retire_upto(struct drm_i915_gem_request *req);
static inline struct drm_i915_gem_request *
to_request(struct dma_fence *fence)
{
/* We assume that NULL fence/request are interoperable */
BUILD_BUG_ON(offsetof(struct drm_i915_gem_request, fence) != 0);
GEM_BUG_ON(fence && !dma_fence_is_i915(fence));
return container_of(fence, struct drm_i915_gem_request, fence);
}
static inline struct drm_i915_gem_request *
i915_gem_request_get(struct drm_i915_gem_request *req)
{
return to_request(dma_fence_get(&req->fence));
}
static inline struct drm_i915_gem_request *
i915_gem_request_get_rcu(struct drm_i915_gem_request *req)
{
return to_request(dma_fence_get_rcu(&req->fence));
}
static inline void
i915_gem_request_put(struct drm_i915_gem_request *req)
{
dma_fence_put(&req->fence);
}
static inline void i915_gem_request_assign(struct drm_i915_gem_request **pdst,
struct drm_i915_gem_request *src)
{
if (src)
i915_gem_request_get(src);
if (*pdst)
i915_gem_request_put(*pdst);
*pdst = src;
}
/**
* i915_gem_request_global_seqno - report the current global seqno
* @request - the request
*
* A request is assigned a global seqno only when it is on the hardware
* execution queue. The global seqno can be used to maintain a list of
* requests on the same engine in retirement order, for example for
* constructing a priority queue for waiting. Prior to its execution, or
* if it is subsequently removed in the event of preemption, its global
* seqno is zero. As both insertion and removal from the execution queue
* may operate in IRQ context, it is not guarded by the usual struct_mutex
* BKL. Instead those relying on the global seqno must be prepared for its
* value to change between reads. Only when the request is complete can
* the global seqno be stable (due to the memory barriers on submitting
* the commands to the hardware to write the breadcrumb, if the HWS shows
* that it has passed the global seqno and the global seqno is unchanged
* after the read, it is indeed complete).
*/
static u32
i915_gem_request_global_seqno(const struct drm_i915_gem_request *request)
{
return READ_ONCE(request->global_seqno);
}
int
i915_gem_request_await_object(struct drm_i915_gem_request *to,
struct drm_i915_gem_object *obj,
bool write);
int i915_gem_request_await_dma_fence(struct drm_i915_gem_request *req,
struct dma_fence *fence);
void __i915_add_request(struct drm_i915_gem_request *req, bool flush_caches);
#define i915_add_request(req) \
__i915_add_request(req, false)
void __i915_gem_request_submit(struct drm_i915_gem_request *request);
void i915_gem_request_submit(struct drm_i915_gem_request *request);
void __i915_gem_request_unsubmit(struct drm_i915_gem_request *request);
void i915_gem_request_unsubmit(struct drm_i915_gem_request *request);
struct intel_rps_client;
#define NO_WAITBOOST ERR_PTR(-1)
#define IS_RPS_CLIENT(p) (!IS_ERR(p))
#define IS_RPS_USER(p) (!IS_ERR_OR_NULL(p))
long i915_wait_request(struct drm_i915_gem_request *req,
unsigned int flags,
long timeout)
__attribute__((nonnull(1)));
#define I915_WAIT_INTERRUPTIBLE BIT(0)
#define I915_WAIT_LOCKED BIT(1) /* struct_mutex held, handle GPU reset */
#define I915_WAIT_ALL BIT(2) /* used by i915_gem_object_wait() */
static inline u32 intel_engine_get_seqno(struct intel_engine_cs *engine);
/**
* Returns true if seq1 is later than seq2.
*/
static inline bool i915_seqno_passed(u32 seq1, u32 seq2)
{
return (s32)(seq1 - seq2) >= 0;
}
static inline bool
__i915_gem_request_started(const struct drm_i915_gem_request *req, u32 seqno)
{
GEM_BUG_ON(!seqno);
return i915_seqno_passed(intel_engine_get_seqno(req->engine),
seqno - 1);
}
static inline bool
i915_gem_request_started(const struct drm_i915_gem_request *req)
{
u32 seqno;
seqno = i915_gem_request_global_seqno(req);
if (!seqno)
return false;
return __i915_gem_request_started(req, seqno);
}
static inline bool
__i915_gem_request_completed(const struct drm_i915_gem_request *req, u32 seqno)
{
GEM_BUG_ON(!seqno);
return i915_seqno_passed(intel_engine_get_seqno(req->engine), seqno) &&
seqno == i915_gem_request_global_seqno(req);
}
static inline bool
i915_gem_request_completed(const struct drm_i915_gem_request *req)
{
u32 seqno;
seqno = i915_gem_request_global_seqno(req);
if (!seqno)
return false;
return __i915_gem_request_completed(req, seqno);
}
bool __i915_spin_request(const struct drm_i915_gem_request *request,
u32 seqno, int state, unsigned long timeout_us);
static inline bool i915_spin_request(const struct drm_i915_gem_request *request,
int state, unsigned long timeout_us)
{
u32 seqno;
seqno = i915_gem_request_global_seqno(request);
if (!seqno)
return 0;
return (__i915_gem_request_started(request, seqno) &&
__i915_spin_request(request, seqno, state, timeout_us));
}
/* 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_gem_active to track the most recent (in
* retirement order) request relevant for the desired mode of access.
* The #i915_gem_active is updated with i915_gem_active_set() to track the
* most recent fence request, typically this is done as part of
* i915_vma_move_to_active().
*
* When the #i915_gem_active completes (is retired), it will
* signal its completion to the owner through a callback as well as mark
* itself as idle (i915_gem_active.request == NULL). The owner
* can then perform any action, such as delayed freeing of an active
* resource including itself.
*/
struct i915_gem_active;
typedef void (*i915_gem_retire_fn)(struct i915_gem_active *,
struct drm_i915_gem_request *);
struct i915_gem_active {
struct drm_i915_gem_request __rcu *request;
struct list_head link;
i915_gem_retire_fn retire;
};
void i915_gem_retire_noop(struct i915_gem_active *,
struct drm_i915_gem_request *request);
/**
* init_request_active - prepares the activity tracker for use
* @active - the active tracker
* @func - a callback when then the tracker is retired (becomes idle),
* can be NULL
*
* init_request_active() 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
init_request_active(struct i915_gem_active *active,
i915_gem_retire_fn retire)
{
INIT_LIST_HEAD(&active->link);
active->retire = retire ?: i915_gem_retire_noop;
}
/**
* i915_gem_active_set - updates the tracker to watch the current request
* @active - the active tracker
* @request - the request to watch
*
* i915_gem_active_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_gem_active_set(struct i915_gem_active *active,
struct drm_i915_gem_request *request)
{
list_move(&active->link, &request->active_list);
rcu_assign_pointer(active->request, request);
}
/**
* i915_gem_active_set_retire_fn - updates the retirement callback
* @active - the active tracker
* @fn - the routine called when the request is retired
* @mutex - struct_mutex used to guard retirements
*
* i915_gem_active_set_retire_fn() updates the function pointer that
* is called when the final request associated with the @active tracker
* is retired.
*/
static inline void
i915_gem_active_set_retire_fn(struct i915_gem_active *active,
i915_gem_retire_fn fn,
struct mutex *mutex)
{
lockdep_assert_held(mutex);
active->retire = fn ?: i915_gem_retire_noop;
}
static inline struct drm_i915_gem_request *
__i915_gem_active_peek(const struct i915_gem_active *active)
{
/* Inside the error capture (running with the driver in an unknown
* state), we want to bend the rules slightly (a lot).
*
* Work is in progress to make it safer, in the meantime this keeps
* the known issue from spamming the logs.
*/
return rcu_dereference_protected(active->request, 1);
}
/**
* i915_gem_active_raw - return the active request
* @active - the active tracker
*
* i915_gem_active_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 drm_i915_gem_request *
i915_gem_active_raw(const struct i915_gem_active *active, struct mutex *mutex)
{
return rcu_dereference_protected(active->request,
lockdep_is_held(mutex));
}
/**
* i915_gem_active_peek - report the active request being monitored
* @active - the active tracker
*
* i915_gem_active_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 drm_i915_gem_request *
i915_gem_active_peek(const struct i915_gem_active *active, struct mutex *mutex)
{
struct drm_i915_gem_request *request;
request = i915_gem_active_raw(active, mutex);
if (!request || i915_gem_request_completed(request))
return NULL;
return request;
}
/**
* i915_gem_active_get - return a reference to the active request
* @active - the active tracker
*
* i915_gem_active_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 drm_i915_gem_request *
i915_gem_active_get(const struct i915_gem_active *active, struct mutex *mutex)
{
return i915_gem_request_get(i915_gem_active_peek(active, mutex));
}
/**
* __i915_gem_active_get_rcu - return a reference to the active request
* @active - the active tracker
*
* __i915_gem_active_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 drm_i915_gem_request *
__i915_gem_active_get_rcu(const struct i915_gem_active *active)
{
/* Performing a lockless retrieval of the active request is super
* tricky. SLAB_DESTROY_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
*
* req = active.request
* retire(req) -> free(req);
* (req is now first on the slab freelist)
* active.request = NULL
*
* req = new submission on a new object
* ref(req)
*
* 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_gem_request_alloc().
*/
do {
struct drm_i915_gem_request *request;
request = rcu_dereference(active->request);
if (!request || i915_gem_request_completed(request))
return NULL;
/* An especially silly compiler could decide to recompute the
* result of i915_gem_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_gem_request_get_rcu, but not executing
* that while still executing i915_gem_request_put() creates
* havoc enough. Prevent this with a compiler barrier.
*/
barrier();
request = i915_gem_request_get_rcu(request);
/* What stops the following rcu_access_pointer() from occurring
* before the above i915_gem_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_gem_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_gem_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_gem_request_put(request);
} while (1);
}
/**
* i915_gem_active_get_unlocked - return a reference to the active request
* @active - the active tracker
*
* i915_gem_active_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_gem_request_put().
*/
static inline struct drm_i915_gem_request *
i915_gem_active_get_unlocked(const struct i915_gem_active *active)
{
struct drm_i915_gem_request *request;
rcu_read_lock();
request = __i915_gem_active_get_rcu(active);
rcu_read_unlock();
return request;
}
/**
* i915_gem_active_isset - report whether the active tracker is assigned
* @active - the active tracker
*
* i915_gem_active_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_gem_active_isset(const struct i915_gem_active *active)
{
return rcu_access_pointer(active->request);
}
/**
* i915_gem_active_wait - waits until the request is completed
* @active - the active request on which to wait
* @flags - how to wait
* @timeout - how long to wait at most
* @rps - userspace client to charge for a waitboost
*
* i915_gem_active_wait() waits until the request is completed before
* returning, without requiring any locks to be held. Note that it does not
* retire any requests before returning.
*
* This function relies on RCU in order to acquire the reference to the active
* request without holding any locks. See __i915_gem_active_get_rcu() for the
* glory details on how that is managed. Once the reference is acquired, we
* can then wait upon the request, and afterwards release our reference,
* free of any locking.
*
* This function wraps i915_wait_request(), see it for the full details on
* the arguments.
*
* Returns 0 if successful, or a negative error code.
*/
static inline int
i915_gem_active_wait(const struct i915_gem_active *active, unsigned int flags)
{
struct drm_i915_gem_request *request;
long ret = 0;
request = i915_gem_active_get_unlocked(active);
if (request) {
ret = i915_wait_request(request, flags, MAX_SCHEDULE_TIMEOUT);
i915_gem_request_put(request);
}
return ret < 0 ? ret : 0;
}
/**
* i915_gem_active_retire - waits until the request is retired
* @active - the active request on which to wait
*
* i915_gem_active_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_gem_active_retire(struct i915_gem_active *active,
struct mutex *mutex)
{
struct drm_i915_gem_request *request;
long ret;
request = i915_gem_active_raw(active, mutex);
if (!request)
return 0;
ret = i915_wait_request(request,
I915_WAIT_INTERRUPTIBLE | I915_WAIT_LOCKED,
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;
}
#define for_each_active(mask, idx) \
for (; mask ? idx = ffs(mask) - 1, 1 : 0; mask &= ~BIT(idx))
#endif /* I915_GEM_REQUEST_H */