drm/xe: Remove special casing for LR queues in submission

	 */

#define MAX_STATIC_MSG_TYPE	3

	struct xe_sched_msg static_msgs[MAX_STATIC_MSG_TYPE];

	/** @lr_tdr: long running TDR worker */

	struct work_struct lr_tdr;

	/** @destroy_async: do final destroy async from this worker */

	struct work_struct destroy_async;

	/** @resume_time: time of last resume */

	/** to wakeup xe_wait_user_fence ioctl if exec queue is reset */

	wake_up_all(&xe->ufence_wq);

	if (xe_exec_queue_is_lr(q))

		queue_work(guc_to_gt(guc)->ordered_wq, &q->guc->lr_tdr);

	else

	xe_sched_tdr_queue_imm(&q->guc->sched);

}

		parallel_write(xe, map, wq_desc.wq_status, WQ_STATUS_ACTIVE);

	}

	/*

	 * We must keep a reference for LR engines if engine is registered with

	 * the GuC as jobs signal immediately and can't destroy an engine if the

	 * GuC has a reference to it.

	 */

	if (xe_exec_queue_is_lr(q))

		xe_exec_queue_get(q);

	set_exec_queue_registered(q);

	trace_xe_exec_queue_register(q);

	if (xe_exec_queue_is_multi_queue_primary(q))

	struct xe_sched_job *job = to_xe_sched_job(drm_job);

	struct xe_exec_queue *q = job->q;

	struct xe_guc *guc = exec_queue_to_guc(q);

	bool lr = xe_exec_queue_is_lr(q), killed_or_banned_or_wedged =

	bool killed_or_banned_or_wedged =

		exec_queue_killed_or_banned_or_wedged(q);

	xe_gt_assert(guc_to_gt(guc), !(exec_queue_destroyed(q) || exec_queue_pending_disable(q)) ||

	}

run_job_out:

	/*

	 * We don't care about job-fence ordering in LR VMs because these fences

	 * are never exported; they are used solely to keep jobs on the pending

	 * list. Once a queue enters an error state, there's no need to track

	 * them.

	 */

	if (killed_or_banned_or_wedged && lr)

		xe_sched_job_set_error(job, -ECANCELED);

	return job->fence;

}

		xe_gt_warn(q->gt, "Pending enable/disable failed to respond\n");

		xe_sched_submission_start(sched);

		xe_gt_reset_async(q->gt);

		if (!xe_exec_queue_is_lr(q))

		xe_sched_tdr_queue_imm(sched);

		return;

	}

	return true;

}

static void xe_guc_exec_queue_lr_cleanup(struct work_struct *w)

{

	struct xe_guc_exec_queue *ge =

		container_of(w, struct xe_guc_exec_queue, lr_tdr);

	struct xe_exec_queue *q = ge->q;

	struct xe_guc *guc = exec_queue_to_guc(q);

	struct xe_gpu_scheduler *sched = &ge->sched;

	struct drm_sched_job *job;

	bool wedged = false;

	xe_gt_assert(guc_to_gt(guc), xe_exec_queue_is_lr(q));

	if (vf_recovery(guc))

		return;

	trace_xe_exec_queue_lr_cleanup(q);

	if (!exec_queue_killed(q))

		wedged = guc_submit_hint_wedged(exec_queue_to_guc(q));

	/* Kill the run_job / process_msg entry points */

	xe_sched_submission_stop(sched);

	/*

	 * Engine state now mostly stable, disable scheduling / deregister if

	 * needed. This cleanup routine might be called multiple times, where

	 * the actual async engine deregister drops the final engine ref.

	 * Calling disable_scheduling_deregister will mark the engine as

	 * destroyed and fire off the CT requests to disable scheduling /

	 * deregister, which we only want to do once. We also don't want to mark

	 * the engine as pending_disable again as this may race with the

	 * xe_guc_deregister_done_handler() which treats it as an unexpected

	 * state.

	 */

	if (!wedged && exec_queue_registered(q) && !exec_queue_destroyed(q)) {

		struct xe_guc *guc = exec_queue_to_guc(q);

		int ret;

		set_exec_queue_banned(q);

		disable_scheduling_deregister(guc, q);

		/*

		 * Must wait for scheduling to be disabled before signalling

		 * any fences, if GT broken the GT reset code should signal us.

		 */

		ret = wait_event_timeout(guc->ct.wq,

					 !exec_queue_pending_disable(q) ||

					 xe_guc_read_stopped(guc) ||

					 vf_recovery(guc), HZ * 5);

		if (vf_recovery(guc))

			return;

		if (!ret) {

			xe_gt_warn(q->gt, "Schedule disable failed to respond, guc_id=%d\n",

				   q->guc->id);

			xe_devcoredump(q, NULL, "Schedule disable failed to respond, guc_id=%d\n",

				       q->guc->id);

			xe_sched_submission_start(sched);

			xe_gt_reset_async(q->gt);

			return;

		}

	}

	if (!exec_queue_killed(q) && !xe_lrc_ring_is_idle(q->lrc[0]))

		xe_devcoredump(q, NULL, "LR job cleanup, guc_id=%d", q->guc->id);

	drm_sched_for_each_pending_job(job, &sched->base, NULL)

		xe_sched_job_set_error(to_xe_sched_job(job), -ECANCELED);

	xe_sched_submission_start(sched);

}

#define ADJUST_FIVE_PERCENT(__t)	mul_u64_u32_div(__t, 105, 100)

static bool check_timeout(struct xe_exec_queue *q, struct xe_sched_job *job)

		xe_gt_warn(guc_to_gt(guc), "Schedule enable failed to respond");

		set_exec_queue_banned(q);

		xe_gt_reset_async(q->gt);

		if (!xe_exec_queue_is_lr(q))

		xe_sched_tdr_queue_imm(&q->guc->sched);

	}

}

	pid_t pid = -1;

	bool wedged = false, skip_timeout_check;

	xe_gt_assert(guc_to_gt(guc), !xe_exec_queue_is_lr(q));

	xe_gt_assert(guc_to_gt(guc), !exec_queue_destroyed(q));

	/*

	    READ_ONCE(q->multi_queue.group->banned))

		skip_timeout_check = true;

	/* LR jobs can only get here if queue has been killed or hit an error */

	if (xe_exec_queue_is_lr(q))

		xe_gt_assert(guc_to_gt(guc), skip_timeout_check);

	/*

	 * FIXME: In multi-queue scenario, the TDR must ensure that the whole

	 * multi-queue group is off the HW before signaling the fences to avoid

		mutex_unlock(&group->list_lock);

	}

	if (xe_exec_queue_is_lr(q))

		cancel_work_sync(&ge->lr_tdr);

	/* Confirm no work left behind accessing device structures */

	cancel_delayed_work_sync(&ge->sched.base.work_tdr);

	if (err)

		goto err_sched;

	if (xe_exec_queue_is_lr(q))

		INIT_WORK(&q->guc->lr_tdr, xe_guc_exec_queue_lr_cleanup);

	mutex_lock(&guc->submission_state.lock);

	err = alloc_guc_id(guc, q);

	/* Clean up lost G2H + reset engine state */

	if (exec_queue_registered(q)) {

		if (xe_exec_queue_is_lr(q))

			xe_exec_queue_put(q);

		else if (exec_queue_destroyed(q))

		if (exec_queue_destroyed(q))

			__guc_exec_queue_destroy(guc, q);

	}

	if (q->guc->suspend_pending) {

				trace_xe_sched_job_ban(job);

				ban = true;

			}

		} else if (xe_exec_queue_is_lr(q) &&

			   !xe_lrc_ring_is_idle(q->lrc[0])) {

			ban = true;

		}

		if (ban) {

	if (pending_enable && !pending_resume &&

	    !exec_queue_pending_tdr_exit(q)) {

		clear_exec_queue_registered(q);

		if (xe_exec_queue_is_lr(q))

			xe_exec_queue_put(q);

		xe_gt_dbg(guc_to_gt(guc), "Replay REGISTER - guc_id=%d",

			  q->guc->id);

	}

	/* Stop scheduling + flush any DRM scheduler operations */

	xe_sched_submission_stop(sched);

	if (xe_exec_queue_is_lr(q))

		cancel_work_sync(&q->guc->lr_tdr);

	else

	cancel_delayed_work_sync(&sched->base.work_tdr);

	guc_exec_queue_revert_pending_state_change(guc, q);

	trace_xe_exec_queue_deregister_done(q);

	clear_exec_queue_registered(q);

	if (xe_exec_queue_is_lr(q))

		xe_exec_queue_put(q);

	else

	__guc_exec_queue_destroy(guc, q);

}

	     TP_ARGS(q)

);

DEFINE_EVENT(xe_exec_queue, xe_exec_queue_lr_cleanup,

	     TP_PROTO(struct xe_exec_queue *q),

	     TP_ARGS(q)

);

DECLARE_EVENT_CLASS(xe_sched_job,

		    TP_PROTO(struct xe_sched_job *job),

		    TP_ARGS(job),