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linux/drivers/gpu/drm/xe/xe_guc_submit.c
Matthew Brost e0f82655df drm/xe: Trigger queue cleanup if not in wedged mode 2 
The intent of wedging a device is to allow queues to continue running
only in wedged mode 2. In other modes, queues should initiate cleanup
and signal all remaining fences. Fix xe_guc_submit_wedge to correctly
clean up queues when wedge mode != 2.

Fixes: 7dbe8af13c ("drm/xe: Wedge the entire device")
Cc: stable@vger.kernel.org
Reviewed-by: Zhanjun Dong <zhanjun.dong@intel.com>
Signed-off-by: Matthew Brost <matthew.brost@intel.com>
Link: https://patch.msgid.link/20260310225039.1320161-4-zhanjun.dong@intel.com
(cherry picked from commit e25ba41c8227c5393c16e4aab398076014bd345f)
Signed-off-by: Thomas Hellström <thomas.hellstrom@linux.intel.com>
2026-03-19 14:22:33 +01:00

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// SPDX-License-Identifier: MIT
/*
* Copyright © 2022 Intel Corporation
*/
#include "xe_guc_submit.h"
#include <linux/bitfield.h>
#include <linux/bitmap.h>
#include <linux/circ_buf.h>
#include <linux/delay.h>
#include <linux/dma-fence-array.h>
#include <linux/math64.h>
#include <drm/drm_managed.h>
#include "abi/guc_actions_abi.h"
#include "abi/guc_actions_slpc_abi.h"
#include "abi/guc_klvs_abi.h"
#include "xe_assert.h"
#include "xe_bo.h"
#include "xe_devcoredump.h"
#include "xe_device.h"
#include "xe_exec_queue.h"
#include "xe_force_wake.h"
#include "xe_gpu_scheduler.h"
#include "xe_gt.h"
#include "xe_gt_clock.h"
#include "xe_gt_printk.h"
#include "xe_guc.h"
#include "xe_guc_capture.h"
#include "xe_guc_ct.h"
#include "xe_guc_exec_queue_types.h"
#include "xe_guc_id_mgr.h"
#include "xe_guc_klv_helpers.h"
#include "xe_guc_submit_types.h"
#include "xe_hw_engine.h"
#include "xe_lrc.h"
#include "xe_macros.h"
#include "xe_map.h"
#include "xe_mocs.h"
#include "xe_pm.h"
#include "xe_ring_ops_types.h"
#include "xe_sched_job.h"
#include "xe_trace.h"
#include "xe_uc_fw.h"
#include "xe_vm.h"
#define XE_GUC_EXEC_QUEUE_CGP_CONTEXT_ERROR_LEN 6
static int guc_submit_reset_prepare(struct xe_guc *guc);
static struct xe_guc *
exec_queue_to_guc(struct xe_exec_queue *q)
{
return &q->gt->uc.guc;
}
/*
* Helpers for engine state, using an atomic as some of the bits can transition
* as the same time (e.g. a suspend can be happning at the same time as schedule
* engine done being processed).
*/
#define EXEC_QUEUE_STATE_REGISTERED (1 << 0)
#define EXEC_QUEUE_STATE_ENABLED (1 << 1)
#define EXEC_QUEUE_STATE_PENDING_ENABLE (1 << 2)
#define EXEC_QUEUE_STATE_PENDING_DISABLE (1 << 3)
#define EXEC_QUEUE_STATE_DESTROYED (1 << 4)
#define EXEC_QUEUE_STATE_SUSPENDED (1 << 5)
#define EXEC_QUEUE_STATE_RESET (1 << 6)
#define EXEC_QUEUE_STATE_KILLED (1 << 7)
#define EXEC_QUEUE_STATE_WEDGED (1 << 8)
#define EXEC_QUEUE_STATE_BANNED (1 << 9)
#define EXEC_QUEUE_STATE_PENDING_RESUME (1 << 10)
#define EXEC_QUEUE_STATE_IDLE_SKIP_SUSPEND (1 << 11)
static bool exec_queue_registered(struct xe_exec_queue *q)
{
return atomic_read(&q->guc->state) & EXEC_QUEUE_STATE_REGISTERED;
}
static void set_exec_queue_registered(struct xe_exec_queue *q)
{
atomic_or(EXEC_QUEUE_STATE_REGISTERED, &q->guc->state);
}
static void clear_exec_queue_registered(struct xe_exec_queue *q)
{
atomic_and(~EXEC_QUEUE_STATE_REGISTERED, &q->guc->state);
}
static bool exec_queue_enabled(struct xe_exec_queue *q)
{
return atomic_read(&q->guc->state) & EXEC_QUEUE_STATE_ENABLED;
}
static void set_exec_queue_enabled(struct xe_exec_queue *q)
{
atomic_or(EXEC_QUEUE_STATE_ENABLED, &q->guc->state);
}
static void clear_exec_queue_enabled(struct xe_exec_queue *q)
{
atomic_and(~EXEC_QUEUE_STATE_ENABLED, &q->guc->state);
}
static bool exec_queue_pending_enable(struct xe_exec_queue *q)
{
return atomic_read(&q->guc->state) & EXEC_QUEUE_STATE_PENDING_ENABLE;
}
static void set_exec_queue_pending_enable(struct xe_exec_queue *q)
{
atomic_or(EXEC_QUEUE_STATE_PENDING_ENABLE, &q->guc->state);
}
static void clear_exec_queue_pending_enable(struct xe_exec_queue *q)
{
atomic_and(~EXEC_QUEUE_STATE_PENDING_ENABLE, &q->guc->state);
}
static bool exec_queue_pending_disable(struct xe_exec_queue *q)
{
return atomic_read(&q->guc->state) & EXEC_QUEUE_STATE_PENDING_DISABLE;
}
static void set_exec_queue_pending_disable(struct xe_exec_queue *q)
{
atomic_or(EXEC_QUEUE_STATE_PENDING_DISABLE, &q->guc->state);
}
static void clear_exec_queue_pending_disable(struct xe_exec_queue *q)
{
atomic_and(~EXEC_QUEUE_STATE_PENDING_DISABLE, &q->guc->state);
}
static bool exec_queue_destroyed(struct xe_exec_queue *q)
{
return atomic_read(&q->guc->state) & EXEC_QUEUE_STATE_DESTROYED;
}
static void set_exec_queue_destroyed(struct xe_exec_queue *q)
{
atomic_or(EXEC_QUEUE_STATE_DESTROYED, &q->guc->state);
}
static void clear_exec_queue_destroyed(struct xe_exec_queue *q)
{
atomic_and(~EXEC_QUEUE_STATE_DESTROYED, &q->guc->state);
}
static bool exec_queue_banned(struct xe_exec_queue *q)
{
return atomic_read(&q->guc->state) & EXEC_QUEUE_STATE_BANNED;
}
static void set_exec_queue_banned(struct xe_exec_queue *q)
{
atomic_or(EXEC_QUEUE_STATE_BANNED, &q->guc->state);
}
static bool exec_queue_suspended(struct xe_exec_queue *q)
{
return atomic_read(&q->guc->state) & EXEC_QUEUE_STATE_SUSPENDED;
}
static void set_exec_queue_suspended(struct xe_exec_queue *q)
{
atomic_or(EXEC_QUEUE_STATE_SUSPENDED, &q->guc->state);
}
static void clear_exec_queue_suspended(struct xe_exec_queue *q)
{
atomic_and(~EXEC_QUEUE_STATE_SUSPENDED, &q->guc->state);
}
static bool exec_queue_reset(struct xe_exec_queue *q)
{
return atomic_read(&q->guc->state) & EXEC_QUEUE_STATE_RESET;
}
static void set_exec_queue_reset(struct xe_exec_queue *q)
{
atomic_or(EXEC_QUEUE_STATE_RESET, &q->guc->state);
}
static bool exec_queue_killed(struct xe_exec_queue *q)
{
return atomic_read(&q->guc->state) & EXEC_QUEUE_STATE_KILLED;
}
static void set_exec_queue_killed(struct xe_exec_queue *q)
{
atomic_or(EXEC_QUEUE_STATE_KILLED, &q->guc->state);
}
static bool exec_queue_wedged(struct xe_exec_queue *q)
{
return atomic_read(&q->guc->state) & EXEC_QUEUE_STATE_WEDGED;
}
static void set_exec_queue_wedged(struct xe_exec_queue *q)
{
atomic_or(EXEC_QUEUE_STATE_WEDGED, &q->guc->state);
}
static bool exec_queue_pending_resume(struct xe_exec_queue *q)
{
return atomic_read(&q->guc->state) & EXEC_QUEUE_STATE_PENDING_RESUME;
}
static void set_exec_queue_pending_resume(struct xe_exec_queue *q)
{
atomic_or(EXEC_QUEUE_STATE_PENDING_RESUME, &q->guc->state);
}
static void clear_exec_queue_pending_resume(struct xe_exec_queue *q)
{
atomic_and(~EXEC_QUEUE_STATE_PENDING_RESUME, &q->guc->state);
}
static bool exec_queue_idle_skip_suspend(struct xe_exec_queue *q)
{
return atomic_read(&q->guc->state) & EXEC_QUEUE_STATE_IDLE_SKIP_SUSPEND;
}
static void set_exec_queue_idle_skip_suspend(struct xe_exec_queue *q)
{
atomic_or(EXEC_QUEUE_STATE_IDLE_SKIP_SUSPEND, &q->guc->state);
}
static void clear_exec_queue_idle_skip_suspend(struct xe_exec_queue *q)
{
atomic_and(~EXEC_QUEUE_STATE_IDLE_SKIP_SUSPEND, &q->guc->state);
}
static bool exec_queue_killed_or_banned_or_wedged(struct xe_exec_queue *q)
{
return (atomic_read(&q->guc->state) &
(EXEC_QUEUE_STATE_WEDGED | EXEC_QUEUE_STATE_KILLED |
EXEC_QUEUE_STATE_BANNED));
}
static void guc_submit_sw_fini(struct drm_device *drm, void *arg)
{
struct xe_guc *guc = arg;
struct xe_device *xe = guc_to_xe(guc);
struct xe_gt *gt = guc_to_gt(guc);
int ret;
ret = wait_event_timeout(guc->submission_state.fini_wq,
xa_empty(&guc->submission_state.exec_queue_lookup),
HZ * 5);
drain_workqueue(xe->destroy_wq);
xe_gt_assert(gt, ret);
xa_destroy(&guc->submission_state.exec_queue_lookup);
}
static void guc_submit_fini(void *arg)
{
struct xe_guc *guc = arg;
/* Forcefully kill any remaining exec queues */
xe_guc_ct_stop(&guc->ct);
guc_submit_reset_prepare(guc);
xe_guc_softreset(guc);
xe_guc_submit_stop(guc);
xe_uc_fw_sanitize(&guc->fw);
xe_guc_submit_pause_abort(guc);
}
static void guc_submit_wedged_fini(void *arg)
{
struct xe_guc *guc = arg;
struct xe_exec_queue *q;
unsigned long index;
mutex_lock(&guc->submission_state.lock);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q) {
if (exec_queue_wedged(q)) {
mutex_unlock(&guc->submission_state.lock);
xe_exec_queue_put(q);
mutex_lock(&guc->submission_state.lock);
}
}
mutex_unlock(&guc->submission_state.lock);
}
static const struct xe_exec_queue_ops guc_exec_queue_ops;
static void primelockdep(struct xe_guc *guc)
{
if (!IS_ENABLED(CONFIG_LOCKDEP))
return;
fs_reclaim_acquire(GFP_KERNEL);
mutex_lock(&guc->submission_state.lock);
mutex_unlock(&guc->submission_state.lock);
fs_reclaim_release(GFP_KERNEL);
}
/**
* xe_guc_submit_init() - Initialize GuC submission.
* @guc: the &xe_guc to initialize
* @num_ids: number of GuC context IDs to use
*
* The bare-metal or PF driver can pass ~0 as &num_ids to indicate that all
* GuC context IDs supported by the GuC firmware should be used for submission.
*
* Only VF drivers will have to provide explicit number of GuC context IDs
* that they can use for submission.
*
* Return: 0 on success or a negative error code on failure.
*/
int xe_guc_submit_init(struct xe_guc *guc, unsigned int num_ids)
{
struct xe_device *xe = guc_to_xe(guc);
struct xe_gt *gt = guc_to_gt(guc);
int err;
err = drmm_mutex_init(&xe->drm, &guc->submission_state.lock);
if (err)
return err;
err = xe_guc_id_mgr_init(&guc->submission_state.idm, num_ids);
if (err)
return err;
gt->exec_queue_ops = &guc_exec_queue_ops;
xa_init(&guc->submission_state.exec_queue_lookup);
init_waitqueue_head(&guc->submission_state.fini_wq);
primelockdep(guc);
guc->submission_state.initialized = true;
err = drmm_add_action_or_reset(&xe->drm, guc_submit_sw_fini, guc);
if (err)
return err;
return devm_add_action_or_reset(xe->drm.dev, guc_submit_fini, guc);
}
/*
* Given that we want to guarantee enough RCS throughput to avoid missing
* frames, we set the yield policy to 20% of each 80ms interval.
*/
#define RC_YIELD_DURATION 80 /* in ms */
#define RC_YIELD_RATIO 20 /* in percent */
static u32 *emit_render_compute_yield_klv(u32 *emit)
{
*emit++ = PREP_GUC_KLV_TAG(SCHEDULING_POLICIES_RENDER_COMPUTE_YIELD);
*emit++ = RC_YIELD_DURATION;
*emit++ = RC_YIELD_RATIO;
return emit;
}
#define SCHEDULING_POLICY_MAX_DWORDS 16
static int guc_init_global_schedule_policy(struct xe_guc *guc)
{
u32 data[SCHEDULING_POLICY_MAX_DWORDS];
u32 *emit = data;
u32 count = 0;
int ret;
if (GUC_SUBMIT_VER(guc) < MAKE_GUC_VER(1, 1, 0))
return 0;
*emit++ = XE_GUC_ACTION_UPDATE_SCHEDULING_POLICIES_KLV;
if (CCS_INSTANCES(guc_to_gt(guc)))
emit = emit_render_compute_yield_klv(emit);
count = emit - data;
if (count > 1) {
xe_assert(guc_to_xe(guc), count <= SCHEDULING_POLICY_MAX_DWORDS);
ret = xe_guc_ct_send_block(&guc->ct, data, count);
if (ret < 0) {
xe_gt_err(guc_to_gt(guc),
"failed to enable GuC scheduling policies: %pe\n",
ERR_PTR(ret));
return ret;
}
}
return 0;
}
int xe_guc_submit_enable(struct xe_guc *guc)
{
int ret;
ret = guc_init_global_schedule_policy(guc);
if (ret)
return ret;
guc->submission_state.enabled = true;
return 0;
}
void xe_guc_submit_disable(struct xe_guc *guc)
{
guc->submission_state.enabled = false;
}
static void __release_guc_id(struct xe_guc *guc, struct xe_exec_queue *q, u32 xa_count)
{
int i;
lockdep_assert_held(&guc->submission_state.lock);
for (i = 0; i < xa_count; ++i)
xa_erase(&guc->submission_state.exec_queue_lookup, q->guc->id + i);
xe_guc_id_mgr_release_locked(&guc->submission_state.idm,
q->guc->id, q->width);
if (xa_empty(&guc->submission_state.exec_queue_lookup))
wake_up(&guc->submission_state.fini_wq);
}
static int alloc_guc_id(struct xe_guc *guc, struct xe_exec_queue *q)
{
int ret;
int i;
/*
* Must use GFP_NOWAIT as this lock is in the dma fence signalling path,
* worse case user gets -ENOMEM on engine create and has to try again.
*
* FIXME: Have caller pre-alloc or post-alloc /w GFP_KERNEL to prevent
* failure.
*/
lockdep_assert_held(&guc->submission_state.lock);
ret = xe_guc_id_mgr_reserve_locked(&guc->submission_state.idm,
q->width);
if (ret < 0)
return ret;
q->guc->id = ret;
for (i = 0; i < q->width; ++i) {
ret = xa_err(xa_store(&guc->submission_state.exec_queue_lookup,
q->guc->id + i, q, GFP_NOWAIT));
if (ret)
goto err_release;
}
return 0;
err_release:
__release_guc_id(guc, q, i);
return ret;
}
static void release_guc_id(struct xe_guc *guc, struct xe_exec_queue *q)
{
mutex_lock(&guc->submission_state.lock);
__release_guc_id(guc, q, q->width);
mutex_unlock(&guc->submission_state.lock);
}
struct exec_queue_policy {
u32 count;
struct guc_update_exec_queue_policy h2g;
};
static u32 __guc_exec_queue_policy_action_size(struct exec_queue_policy *policy)
{
size_t bytes = sizeof(policy->h2g.header) +
(sizeof(policy->h2g.klv[0]) * policy->count);
return bytes / sizeof(u32);
}
static void __guc_exec_queue_policy_start_klv(struct exec_queue_policy *policy,
u16 guc_id)
{
policy->h2g.header.action =
XE_GUC_ACTION_HOST2GUC_UPDATE_CONTEXT_POLICIES;
policy->h2g.header.guc_id = guc_id;
policy->count = 0;
}
#define MAKE_EXEC_QUEUE_POLICY_ADD(func, id) \
static void __guc_exec_queue_policy_add_##func(struct exec_queue_policy *policy, \
u32 data) \
{ \
XE_WARN_ON(policy->count >= GUC_CONTEXT_POLICIES_KLV_NUM_IDS); \
\
policy->h2g.klv[policy->count].kl = \
FIELD_PREP(GUC_KLV_0_KEY, \
GUC_CONTEXT_POLICIES_KLV_ID_##id) | \
FIELD_PREP(GUC_KLV_0_LEN, 1); \
policy->h2g.klv[policy->count].value = data; \
policy->count++; \
}
MAKE_EXEC_QUEUE_POLICY_ADD(execution_quantum, EXECUTION_QUANTUM)
MAKE_EXEC_QUEUE_POLICY_ADD(preemption_timeout, PREEMPTION_TIMEOUT)
MAKE_EXEC_QUEUE_POLICY_ADD(priority, SCHEDULING_PRIORITY)
MAKE_EXEC_QUEUE_POLICY_ADD(slpc_exec_queue_freq_req, SLPM_GT_FREQUENCY)
#undef MAKE_EXEC_QUEUE_POLICY_ADD
static const int xe_exec_queue_prio_to_guc[] = {
[XE_EXEC_QUEUE_PRIORITY_LOW] = GUC_CLIENT_PRIORITY_NORMAL,
[XE_EXEC_QUEUE_PRIORITY_NORMAL] = GUC_CLIENT_PRIORITY_KMD_NORMAL,
[XE_EXEC_QUEUE_PRIORITY_HIGH] = GUC_CLIENT_PRIORITY_HIGH,
[XE_EXEC_QUEUE_PRIORITY_KERNEL] = GUC_CLIENT_PRIORITY_KMD_HIGH,
};
static void init_policies(struct xe_guc *guc, struct xe_exec_queue *q)
{
struct exec_queue_policy policy;
enum xe_exec_queue_priority prio = q->sched_props.priority;
u32 timeslice_us = q->sched_props.timeslice_us;
u32 slpc_exec_queue_freq_req = 0;
u32 preempt_timeout_us = q->sched_props.preempt_timeout_us;
xe_gt_assert(guc_to_gt(guc), exec_queue_registered(q) &&
!xe_exec_queue_is_multi_queue_secondary(q));
if (q->flags & EXEC_QUEUE_FLAG_LOW_LATENCY)
slpc_exec_queue_freq_req |= SLPC_CTX_FREQ_REQ_IS_COMPUTE;
__guc_exec_queue_policy_start_klv(&policy, q->guc->id);
__guc_exec_queue_policy_add_priority(&policy, xe_exec_queue_prio_to_guc[prio]);
__guc_exec_queue_policy_add_execution_quantum(&policy, timeslice_us);
__guc_exec_queue_policy_add_preemption_timeout(&policy, preempt_timeout_us);
__guc_exec_queue_policy_add_slpc_exec_queue_freq_req(&policy,
slpc_exec_queue_freq_req);
xe_guc_ct_send(&guc->ct, (u32 *)&policy.h2g,
__guc_exec_queue_policy_action_size(&policy), 0, 0);
}
static void set_min_preemption_timeout(struct xe_guc *guc, struct xe_exec_queue *q)
{
struct exec_queue_policy policy;
xe_assert(guc_to_xe(guc), !xe_exec_queue_is_multi_queue_secondary(q));
__guc_exec_queue_policy_start_klv(&policy, q->guc->id);
__guc_exec_queue_policy_add_preemption_timeout(&policy, 1);
xe_guc_ct_send(&guc->ct, (u32 *)&policy.h2g,
__guc_exec_queue_policy_action_size(&policy), 0, 0);
}
static bool vf_recovery(struct xe_guc *guc)
{
return xe_gt_recovery_pending(guc_to_gt(guc));
}
static void xe_guc_exec_queue_trigger_cleanup(struct xe_exec_queue *q)
{
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_device *xe = guc_to_xe(guc);
/** to wakeup xe_wait_user_fence ioctl if exec queue is reset */
wake_up_all(&xe->ufence_wq);
xe_sched_tdr_queue_imm(&q->guc->sched);
}
static void xe_guc_exec_queue_group_trigger_cleanup(struct xe_exec_queue *q)
{
struct xe_exec_queue *primary = xe_exec_queue_multi_queue_primary(q);
struct xe_exec_queue_group *group = q->multi_queue.group;
struct xe_exec_queue *eq;
xe_gt_assert(guc_to_gt(exec_queue_to_guc(q)),
xe_exec_queue_is_multi_queue(q));
/* Group banned, skip timeout check in TDR */
WRITE_ONCE(group->banned, true);
xe_guc_exec_queue_trigger_cleanup(primary);
mutex_lock(&group->list_lock);
list_for_each_entry(eq, &group->list, multi_queue.link)
xe_guc_exec_queue_trigger_cleanup(eq);
mutex_unlock(&group->list_lock);
}
static void xe_guc_exec_queue_reset_trigger_cleanup(struct xe_exec_queue *q)
{
if (xe_exec_queue_is_multi_queue(q)) {
struct xe_exec_queue *primary = xe_exec_queue_multi_queue_primary(q);
struct xe_exec_queue_group *group = q->multi_queue.group;
struct xe_exec_queue *eq;
/* Group banned, skip timeout check in TDR */
WRITE_ONCE(group->banned, true);
set_exec_queue_reset(primary);
if (!exec_queue_banned(primary))
xe_guc_exec_queue_trigger_cleanup(primary);
mutex_lock(&group->list_lock);
list_for_each_entry(eq, &group->list, multi_queue.link) {
set_exec_queue_reset(eq);
if (!exec_queue_banned(eq))
xe_guc_exec_queue_trigger_cleanup(eq);
}
mutex_unlock(&group->list_lock);
} else {
set_exec_queue_reset(q);
if (!exec_queue_banned(q))
xe_guc_exec_queue_trigger_cleanup(q);
}
}
static void set_exec_queue_group_banned(struct xe_exec_queue *q)
{
struct xe_exec_queue *primary = xe_exec_queue_multi_queue_primary(q);
struct xe_exec_queue_group *group = q->multi_queue.group;
struct xe_exec_queue *eq;
/* Ban all queues of the multi-queue group */
xe_gt_assert(guc_to_gt(exec_queue_to_guc(q)),
xe_exec_queue_is_multi_queue(q));
set_exec_queue_banned(primary);
mutex_lock(&group->list_lock);
list_for_each_entry(eq, &group->list, multi_queue.link)
set_exec_queue_banned(eq);
mutex_unlock(&group->list_lock);
}
/* Helper for context registration H2G */
struct guc_ctxt_registration_info {
u32 flags;
u32 context_idx;
u32 engine_class;
u32 engine_submit_mask;
u32 wq_desc_lo;
u32 wq_desc_hi;
u32 wq_base_lo;
u32 wq_base_hi;
u32 wq_size;
u32 cgp_lo;
u32 cgp_hi;
u32 hwlrca_lo;
u32 hwlrca_hi;
};
#define parallel_read(xe_, map_, field_) \
xe_map_rd_field(xe_, &map_, 0, struct guc_submit_parallel_scratch, \
field_)
#define parallel_write(xe_, map_, field_, val_) \
xe_map_wr_field(xe_, &map_, 0, struct guc_submit_parallel_scratch, \
field_, val_)
/**
* DOC: Multi Queue Group GuC interface
*
* The multi queue group coordination between KMD and GuC is through a software
* construct called Context Group Page (CGP). The CGP is a KMD managed 4KB page
* allocated in the global GTT.
*
* CGP format:
*
* +-----------+---------------------------+---------------------------------------------+
* | DWORD | Name | Description |
* +-----------+---------------------------+---------------------------------------------+
* | 0 | Version | Bits [15:8]=Major ver, [7:0]=Minor ver |
* +-----------+---------------------------+---------------------------------------------+
* | 1..15 | RESERVED | MBZ |
* +-----------+---------------------------+---------------------------------------------+
* | 16 | KMD_QUEUE_UPDATE_MASK_DW0 | KMD queue mask for queues 31..0 |
* +-----------+---------------------------+---------------------------------------------+
* | 17 | KMD_QUEUE_UPDATE_MASK_DW1 | KMD queue mask for queues 63..32 |
* +-----------+---------------------------+---------------------------------------------+
* | 18..31 | RESERVED | MBZ |
* +-----------+---------------------------+---------------------------------------------+
* | 32 | Q0CD_DW0 | Queue 0 context LRC descriptor lower DWORD |
* +-----------+---------------------------+---------------------------------------------+
* | 33 | Q0ContextIndex | Context ID for Queue 0 |
* +-----------+---------------------------+---------------------------------------------+
* | 34 | Q1CD_DW0 | Queue 1 context LRC descriptor lower DWORD |
* +-----------+---------------------------+---------------------------------------------+
* | 35 | Q1ContextIndex | Context ID for Queue 1 |
* +-----------+---------------------------+---------------------------------------------+
* | ... |... | ... |
* +-----------+---------------------------+---------------------------------------------+
* | 158 | Q63CD_DW0 | Queue 63 context LRC descriptor lower DWORD |
* +-----------+---------------------------+---------------------------------------------+
* | 159 | Q63ContextIndex | Context ID for Queue 63 |
* +-----------+---------------------------+---------------------------------------------+
* | 160..1024 | RESERVED | MBZ |
* +-----------+---------------------------+---------------------------------------------+
*
* While registering Q0 with GuC, CGP is updated with Q0 entry and GuC is notified
* through XE_GUC_ACTION_REGISTER_CONTEXT_MULTI_QUEUE H2G message which specifies
* the CGP address. When the secondary queues are added to the group, the CGP is
* updated with entry for that queue and GuC is notified through the H2G interface
* XE_GUC_ACTION_MULTI_QUEUE_CONTEXT_CGP_SYNC. GuC responds to these H2G messages
* with a XE_GUC_ACTION_NOTIFY_MULTIQ_CONTEXT_CGP_SYNC_DONE G2H message. GuC also
* sends a XE_GUC_ACTION_NOTIFY_MULTI_QUEUE_CGP_CONTEXT_ERROR notification for any
* error in the CGP. Only one of these CGP update messages can be outstanding
* (waiting for GuC response) at any time. The bits in KMD_QUEUE_UPDATE_MASK_DW*
* fields indicate which queue entry is being updated in the CGP.
*
* The primary queue (Q0) represents the multi queue group context in GuC and
* submission on any queue of the group must be through Q0 GuC interface only.
*
* As it is not required to register secondary queues with GuC, the secondary queue
* context ids in the CGP are populated with Q0 context id.
*/
#define CGP_VERSION_MAJOR_SHIFT 8
static void xe_guc_exec_queue_group_cgp_update(struct xe_device *xe,
struct xe_exec_queue *q)
{
struct xe_exec_queue_group *group = q->multi_queue.group;
u32 guc_id = group->primary->guc->id;
/* Currently implementing CGP version 1.0 */
xe_map_wr(xe, &group->cgp_bo->vmap, 0, u32,
1 << CGP_VERSION_MAJOR_SHIFT);
xe_map_wr(xe, &group->cgp_bo->vmap,
(32 + q->multi_queue.pos * 2) * sizeof(u32),
u32, lower_32_bits(xe_lrc_descriptor(q->lrc[0])));
xe_map_wr(xe, &group->cgp_bo->vmap,
(33 + q->multi_queue.pos * 2) * sizeof(u32),
u32, guc_id);
if (q->multi_queue.pos / 32) {
xe_map_wr(xe, &group->cgp_bo->vmap, 17 * sizeof(u32),
u32, BIT(q->multi_queue.pos % 32));
xe_map_wr(xe, &group->cgp_bo->vmap, 16 * sizeof(u32), u32, 0);
} else {
xe_map_wr(xe, &group->cgp_bo->vmap, 16 * sizeof(u32),
u32, BIT(q->multi_queue.pos));
xe_map_wr(xe, &group->cgp_bo->vmap, 17 * sizeof(u32), u32, 0);
}
}
static void xe_guc_exec_queue_group_cgp_sync(struct xe_guc *guc,
struct xe_exec_queue *q,
const u32 *action, u32 len)
{
struct xe_exec_queue_group *group = q->multi_queue.group;
struct xe_device *xe = guc_to_xe(guc);
long ret;
/*
* As all queues of a multi queue group use single drm scheduler
* submit workqueue, CGP synchronization with GuC are serialized.
* Hence, no locking is required here.
* Wait for any pending CGP_SYNC_DONE response before updating the
* CGP page and sending CGP_SYNC message.
*
* FIXME: Support VF migration
*/
ret = wait_event_timeout(guc->ct.wq,
!READ_ONCE(group->sync_pending) ||
xe_guc_read_stopped(guc), HZ);
if (!ret || xe_guc_read_stopped(guc)) {
/* CGP_SYNC failed. Reset gt, cleanup the group */
xe_gt_warn(guc_to_gt(guc), "Wait for CGP_SYNC_DONE response failed!\n");
set_exec_queue_group_banned(q);
xe_gt_reset_async(q->gt);
xe_guc_exec_queue_group_trigger_cleanup(q);
return;
}
xe_lrc_set_multi_queue_priority(q->lrc[0], q->multi_queue.priority);
xe_guc_exec_queue_group_cgp_update(xe, q);
WRITE_ONCE(group->sync_pending, true);
xe_guc_ct_send(&guc->ct, action, len, G2H_LEN_DW_MULTI_QUEUE_CONTEXT, 1);
}
static void __register_exec_queue_group(struct xe_guc *guc,
struct xe_exec_queue *q,
struct guc_ctxt_registration_info *info)
{
#define MAX_MULTI_QUEUE_REG_SIZE (8)
u32 action[MAX_MULTI_QUEUE_REG_SIZE];
int len = 0;
action[len++] = XE_GUC_ACTION_REGISTER_CONTEXT_MULTI_QUEUE;
action[len++] = info->flags;
action[len++] = info->context_idx;
action[len++] = info->engine_class;
action[len++] = info->engine_submit_mask;
action[len++] = 0; /* Reserved */
action[len++] = info->cgp_lo;
action[len++] = info->cgp_hi;
xe_gt_assert(guc_to_gt(guc), len <= MAX_MULTI_QUEUE_REG_SIZE);
#undef MAX_MULTI_QUEUE_REG_SIZE
/*
* The above XE_GUC_ACTION_REGISTER_CONTEXT_MULTI_QUEUE do expect a
* XE_GUC_ACTION_NOTIFY_MULTI_QUEUE_CONTEXT_CGP_SYNC_DONE response
* from guc.
*/
xe_guc_exec_queue_group_cgp_sync(guc, q, action, len);
}
static void xe_guc_exec_queue_group_add(struct xe_guc *guc,
struct xe_exec_queue *q)
{
#define MAX_MULTI_QUEUE_CGP_SYNC_SIZE (2)
u32 action[MAX_MULTI_QUEUE_CGP_SYNC_SIZE];
int len = 0;
xe_gt_assert(guc_to_gt(guc), xe_exec_queue_is_multi_queue_secondary(q));
action[len++] = XE_GUC_ACTION_MULTI_QUEUE_CONTEXT_CGP_SYNC;
action[len++] = q->multi_queue.group->primary->guc->id;
xe_gt_assert(guc_to_gt(guc), len <= MAX_MULTI_QUEUE_CGP_SYNC_SIZE);
#undef MAX_MULTI_QUEUE_CGP_SYNC_SIZE
/*
* The above XE_GUC_ACTION_MULTI_QUEUE_CONTEXT_CGP_SYNC do expect a
* XE_GUC_ACTION_NOTIFY_MULTI_QUEUE_CONTEXT_CGP_SYNC_DONE response
* from guc.
*/
xe_guc_exec_queue_group_cgp_sync(guc, q, action, len);
}
static void __register_mlrc_exec_queue(struct xe_guc *guc,
struct xe_exec_queue *q,
struct guc_ctxt_registration_info *info)
{
#define MAX_MLRC_REG_SIZE (13 + XE_HW_ENGINE_MAX_INSTANCE * 2)
u32 action[MAX_MLRC_REG_SIZE];
int len = 0;
int i;
xe_gt_assert(guc_to_gt(guc), xe_exec_queue_is_parallel(q));
action[len++] = XE_GUC_ACTION_REGISTER_CONTEXT_MULTI_LRC;
action[len++] = info->flags;
action[len++] = info->context_idx;
action[len++] = info->engine_class;
action[len++] = info->engine_submit_mask;
action[len++] = info->wq_desc_lo;
action[len++] = info->wq_desc_hi;
action[len++] = info->wq_base_lo;
action[len++] = info->wq_base_hi;
action[len++] = info->wq_size;
action[len++] = q->width;
action[len++] = info->hwlrca_lo;
action[len++] = info->hwlrca_hi;
for (i = 1; i < q->width; ++i) {
struct xe_lrc *lrc = q->lrc[i];
action[len++] = lower_32_bits(xe_lrc_descriptor(lrc));
action[len++] = upper_32_bits(xe_lrc_descriptor(lrc));
}
/* explicitly checks some fields that we might fixup later */
xe_gt_assert(guc_to_gt(guc), info->wq_desc_lo ==
action[XE_GUC_REGISTER_CONTEXT_MULTI_LRC_DATA_5_WQ_DESC_ADDR_LOWER]);
xe_gt_assert(guc_to_gt(guc), info->wq_base_lo ==
action[XE_GUC_REGISTER_CONTEXT_MULTI_LRC_DATA_7_WQ_BUF_BASE_LOWER]);
xe_gt_assert(guc_to_gt(guc), q->width ==
action[XE_GUC_REGISTER_CONTEXT_MULTI_LRC_DATA_10_NUM_CTXS]);
xe_gt_assert(guc_to_gt(guc), info->hwlrca_lo ==
action[XE_GUC_REGISTER_CONTEXT_MULTI_LRC_DATA_11_HW_LRC_ADDR]);
xe_gt_assert(guc_to_gt(guc), len <= MAX_MLRC_REG_SIZE);
#undef MAX_MLRC_REG_SIZE
xe_guc_ct_send(&guc->ct, action, len, 0, 0);
}
static void __register_exec_queue(struct xe_guc *guc,
struct guc_ctxt_registration_info *info)
{
u32 action[] = {
XE_GUC_ACTION_REGISTER_CONTEXT,
info->flags,
info->context_idx,
info->engine_class,
info->engine_submit_mask,
info->wq_desc_lo,
info->wq_desc_hi,
info->wq_base_lo,
info->wq_base_hi,
info->wq_size,
info->hwlrca_lo,
info->hwlrca_hi,
};
/* explicitly checks some fields that we might fixup later */
xe_gt_assert(guc_to_gt(guc), info->wq_desc_lo ==
action[XE_GUC_REGISTER_CONTEXT_DATA_5_WQ_DESC_ADDR_LOWER]);
xe_gt_assert(guc_to_gt(guc), info->wq_base_lo ==
action[XE_GUC_REGISTER_CONTEXT_DATA_7_WQ_BUF_BASE_LOWER]);
xe_gt_assert(guc_to_gt(guc), info->hwlrca_lo ==
action[XE_GUC_REGISTER_CONTEXT_DATA_10_HW_LRC_ADDR]);
xe_guc_ct_send(&guc->ct, action, ARRAY_SIZE(action), 0, 0);
}
static void register_exec_queue(struct xe_exec_queue *q, int ctx_type)
{
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_device *xe = guc_to_xe(guc);
struct xe_lrc *lrc = q->lrc[0];
struct guc_ctxt_registration_info info;
xe_gt_assert(guc_to_gt(guc), !exec_queue_registered(q));
xe_gt_assert(guc_to_gt(guc), ctx_type < GUC_CONTEXT_COUNT);
memset(&info, 0, sizeof(info));
info.context_idx = q->guc->id;
info.engine_class = xe_engine_class_to_guc_class(q->class);
info.engine_submit_mask = q->logical_mask;
info.hwlrca_lo = lower_32_bits(xe_lrc_descriptor(lrc));
info.hwlrca_hi = upper_32_bits(xe_lrc_descriptor(lrc));
info.flags = CONTEXT_REGISTRATION_FLAG_KMD |
FIELD_PREP(CONTEXT_REGISTRATION_FLAG_TYPE, ctx_type);
if (xe_exec_queue_is_multi_queue(q)) {
struct xe_exec_queue_group *group = q->multi_queue.group;
info.cgp_lo = xe_bo_ggtt_addr(group->cgp_bo);
info.cgp_hi = 0;
}
if (xe_exec_queue_is_parallel(q)) {
u64 ggtt_addr = xe_lrc_parallel_ggtt_addr(lrc);
struct iosys_map map = xe_lrc_parallel_map(lrc);
info.wq_desc_lo = lower_32_bits(ggtt_addr +
offsetof(struct guc_submit_parallel_scratch, wq_desc));
info.wq_desc_hi = upper_32_bits(ggtt_addr +
offsetof(struct guc_submit_parallel_scratch, wq_desc));
info.wq_base_lo = lower_32_bits(ggtt_addr +
offsetof(struct guc_submit_parallel_scratch, wq[0]));
info.wq_base_hi = upper_32_bits(ggtt_addr +
offsetof(struct guc_submit_parallel_scratch, wq[0]));
info.wq_size = WQ_SIZE;
q->guc->wqi_head = 0;
q->guc->wqi_tail = 0;
xe_map_memset(xe, &map, 0, 0, PARALLEL_SCRATCH_SIZE - WQ_SIZE);
parallel_write(xe, map, wq_desc.wq_status, WQ_STATUS_ACTIVE);
}
set_exec_queue_registered(q);
trace_xe_exec_queue_register(q);
if (xe_exec_queue_is_multi_queue_primary(q))
__register_exec_queue_group(guc, q, &info);
else if (xe_exec_queue_is_parallel(q))
__register_mlrc_exec_queue(guc, q, &info);
else if (!xe_exec_queue_is_multi_queue_secondary(q))
__register_exec_queue(guc, &info);
if (!xe_exec_queue_is_multi_queue_secondary(q))
init_policies(guc, q);
if (xe_exec_queue_is_multi_queue_secondary(q))
xe_guc_exec_queue_group_add(guc, q);
}
static u32 wq_space_until_wrap(struct xe_exec_queue *q)
{
return (WQ_SIZE - q->guc->wqi_tail);
}
static inline void relaxed_ms_sleep(unsigned int delay_ms)
{
unsigned long min_us, max_us;
if (!delay_ms)
return;
if (delay_ms > 20) {
msleep(delay_ms);
return;
}
min_us = mul_u32_u32(delay_ms, 1000);
max_us = min_us + 500;
usleep_range(min_us, max_us);
}
static int wq_wait_for_space(struct xe_exec_queue *q, u32 wqi_size)
{
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_device *xe = guc_to_xe(guc);
struct iosys_map map = xe_lrc_parallel_map(q->lrc[0]);
unsigned int sleep_period_ms = 1, sleep_total_ms = 0;
#define AVAILABLE_SPACE \
CIRC_SPACE(q->guc->wqi_tail, q->guc->wqi_head, WQ_SIZE)
if (wqi_size > AVAILABLE_SPACE && !vf_recovery(guc)) {
try_again:
q->guc->wqi_head = parallel_read(xe, map, wq_desc.head);
if (wqi_size > AVAILABLE_SPACE && !vf_recovery(guc)) {
if (sleep_total_ms > 2000) {
xe_gt_reset_async(q->gt);
return -ENODEV;
}
msleep(sleep_period_ms);
sleep_total_ms += sleep_period_ms;
if (sleep_period_ms < 64)
sleep_period_ms <<= 1;
goto try_again;
}
}
#undef AVAILABLE_SPACE
return 0;
}
static int wq_noop_append(struct xe_exec_queue *q)
{
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_device *xe = guc_to_xe(guc);
struct iosys_map map = xe_lrc_parallel_map(q->lrc[0]);
u32 len_dw = wq_space_until_wrap(q) / sizeof(u32) - 1;
if (wq_wait_for_space(q, wq_space_until_wrap(q)))
return -ENODEV;
xe_gt_assert(guc_to_gt(guc), FIELD_FIT(WQ_LEN_MASK, len_dw));
parallel_write(xe, map, wq[q->guc->wqi_tail / sizeof(u32)],
FIELD_PREP(WQ_TYPE_MASK, WQ_TYPE_NOOP) |
FIELD_PREP(WQ_LEN_MASK, len_dw));
q->guc->wqi_tail = 0;
return 0;
}
static void wq_item_append(struct xe_exec_queue *q)
{
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_device *xe = guc_to_xe(guc);
struct iosys_map map = xe_lrc_parallel_map(q->lrc[0]);
#define WQ_HEADER_SIZE 4 /* Includes 1 LRC address too */
u32 wqi[XE_HW_ENGINE_MAX_INSTANCE + (WQ_HEADER_SIZE - 1)];
u32 wqi_size = (q->width + (WQ_HEADER_SIZE - 1)) * sizeof(u32);
u32 len_dw = (wqi_size / sizeof(u32)) - 1;
int i = 0, j;
if (wqi_size > wq_space_until_wrap(q)) {
if (wq_noop_append(q))
return;
}
if (wq_wait_for_space(q, wqi_size))
return;
wqi[i++] = FIELD_PREP(WQ_TYPE_MASK, WQ_TYPE_MULTI_LRC) |
FIELD_PREP(WQ_LEN_MASK, len_dw);
wqi[i++] = xe_lrc_descriptor(q->lrc[0]);
wqi[i++] = FIELD_PREP(WQ_GUC_ID_MASK, q->guc->id) |
FIELD_PREP(WQ_RING_TAIL_MASK, q->lrc[0]->ring.tail / sizeof(u64));
wqi[i++] = 0;
for (j = 1; j < q->width; ++j) {
struct xe_lrc *lrc = q->lrc[j];
wqi[i++] = lrc->ring.tail / sizeof(u64);
}
xe_gt_assert(guc_to_gt(guc), i == wqi_size / sizeof(u32));
iosys_map_incr(&map, offsetof(struct guc_submit_parallel_scratch,
wq[q->guc->wqi_tail / sizeof(u32)]));
xe_map_memcpy_to(xe, &map, 0, wqi, wqi_size);
q->guc->wqi_tail += wqi_size;
xe_gt_assert(guc_to_gt(guc), q->guc->wqi_tail <= WQ_SIZE);
xe_device_wmb(xe);
map = xe_lrc_parallel_map(q->lrc[0]);
parallel_write(xe, map, wq_desc.tail, q->guc->wqi_tail);
}
#define RESUME_PENDING ~0x0ull
static void submit_exec_queue(struct xe_exec_queue *q, struct xe_sched_job *job)
{
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_lrc *lrc = q->lrc[0];
u32 action[3];
u32 g2h_len = 0;
u32 num_g2h = 0;
int len = 0;
bool extra_submit = false;
xe_gt_assert(guc_to_gt(guc), exec_queue_registered(q));
if (!job->restore_replay || job->last_replay) {
if (xe_exec_queue_is_parallel(q))
wq_item_append(q);
else if (!exec_queue_idle_skip_suspend(q))
xe_lrc_set_ring_tail(lrc, lrc->ring.tail);
job->last_replay = false;
}
if (exec_queue_suspended(q) && !xe_exec_queue_is_parallel(q))
return;
/*
* All queues in a multi-queue group will use the primary queue
* of the group to interface with GuC.
*/
q = xe_exec_queue_multi_queue_primary(q);
if (!exec_queue_enabled(q) && !exec_queue_suspended(q)) {
action[len++] = XE_GUC_ACTION_SCHED_CONTEXT_MODE_SET;
action[len++] = q->guc->id;
action[len++] = GUC_CONTEXT_ENABLE;
g2h_len = G2H_LEN_DW_SCHED_CONTEXT_MODE_SET;
num_g2h = 1;
if (xe_exec_queue_is_parallel(q))
extra_submit = true;
q->guc->resume_time = RESUME_PENDING;
set_exec_queue_pending_enable(q);
set_exec_queue_enabled(q);
trace_xe_exec_queue_scheduling_enable(q);
} else {
action[len++] = XE_GUC_ACTION_SCHED_CONTEXT;
action[len++] = q->guc->id;
trace_xe_exec_queue_submit(q);
}
xe_guc_ct_send(&guc->ct, action, len, g2h_len, num_g2h);
if (extra_submit) {
len = 0;
action[len++] = XE_GUC_ACTION_SCHED_CONTEXT;
action[len++] = q->guc->id;
trace_xe_exec_queue_submit(q);
xe_guc_ct_send(&guc->ct, action, len, 0, 0);
}
}
static struct dma_fence *
guc_exec_queue_run_job(struct drm_sched_job *drm_job)
{
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 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)) ||
exec_queue_banned(q) || exec_queue_suspended(q));
trace_xe_sched_job_run(job);
if (!killed_or_banned_or_wedged && !xe_sched_job_is_error(job)) {
if (xe_exec_queue_is_multi_queue_secondary(q)) {
struct xe_exec_queue *primary = xe_exec_queue_multi_queue_primary(q);
if (exec_queue_killed_or_banned_or_wedged(primary)) {
killed_or_banned_or_wedged = true;
goto run_job_out;
}
if (!exec_queue_registered(primary))
register_exec_queue(primary, GUC_CONTEXT_NORMAL);
}
if (!exec_queue_registered(q))
register_exec_queue(q, GUC_CONTEXT_NORMAL);
if (!job->restore_replay)
q->ring_ops->emit_job(job);
submit_exec_queue(q, job);
job->restore_replay = false;
}
run_job_out:
return job->fence;
}
static void guc_exec_queue_free_job(struct drm_sched_job *drm_job)
{
struct xe_sched_job *job = to_xe_sched_job(drm_job);
trace_xe_sched_job_free(job);
xe_sched_job_put(job);
}
int xe_guc_read_stopped(struct xe_guc *guc)
{
return atomic_read(&guc->submission_state.stopped);
}
static void handle_multi_queue_secondary_sched_done(struct xe_guc *guc,
struct xe_exec_queue *q,
u32 runnable_state);
static void handle_deregister_done(struct xe_guc *guc, struct xe_exec_queue *q);
#define MAKE_SCHED_CONTEXT_ACTION(q, enable_disable) \
u32 action[] = { \
XE_GUC_ACTION_SCHED_CONTEXT_MODE_SET, \
q->guc->id, \
GUC_CONTEXT_##enable_disable, \
}
static void disable_scheduling_deregister(struct xe_guc *guc,
struct xe_exec_queue *q)
{
MAKE_SCHED_CONTEXT_ACTION(q, DISABLE);
int ret;
if (!xe_exec_queue_is_multi_queue_secondary(q))
set_min_preemption_timeout(guc, q);
smp_rmb();
ret = wait_event_timeout(guc->ct.wq,
(!exec_queue_pending_enable(q) &&
!exec_queue_pending_disable(q)) ||
xe_guc_read_stopped(guc) ||
vf_recovery(guc),
HZ * 5);
if (!ret && !vf_recovery(guc)) {
struct xe_gpu_scheduler *sched = &q->guc->sched;
xe_gt_warn(q->gt, "Pending enable/disable failed to respond\n");
xe_sched_submission_start(sched);
xe_gt_reset_async(q->gt);
xe_sched_tdr_queue_imm(sched);
return;
}
clear_exec_queue_enabled(q);
set_exec_queue_pending_disable(q);
set_exec_queue_destroyed(q);
trace_xe_exec_queue_scheduling_disable(q);
/*
* Reserve space for both G2H here as the 2nd G2H is sent from a G2H
* handler and we are not allowed to reserved G2H space in handlers.
*/
if (xe_exec_queue_is_multi_queue_secondary(q))
handle_multi_queue_secondary_sched_done(guc, q, 0);
else
xe_guc_ct_send(&guc->ct, action, ARRAY_SIZE(action),
G2H_LEN_DW_SCHED_CONTEXT_MODE_SET +
G2H_LEN_DW_DEREGISTER_CONTEXT, 2);
}
/**
* xe_guc_submit_wedge() - Wedge GuC submission
* @guc: the GuC object
*
* Save exec queue's registered with GuC state by taking a ref to each queue.
* Register a DRMM handler to drop refs upon driver unload.
*/
void xe_guc_submit_wedge(struct xe_guc *guc)
{
struct xe_device *xe = guc_to_xe(guc);
struct xe_gt *gt = guc_to_gt(guc);
struct xe_exec_queue *q;
unsigned long index;
int err;
xe_gt_assert(guc_to_gt(guc), guc_to_xe(guc)->wedged.mode);
/*
* If device is being wedged even before submission_state is
* initialized, there's nothing to do here.
*/
if (!guc->submission_state.initialized)
return;
if (xe->wedged.mode == 2) {
err = devm_add_action_or_reset(guc_to_xe(guc)->drm.dev,
guc_submit_wedged_fini, guc);
if (err) {
xe_gt_err(gt, "Failed to register clean-up on wedged.mode=2; "
"Although device is wedged.\n");
return;
}
mutex_lock(&guc->submission_state.lock);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q)
if (xe_exec_queue_get_unless_zero(q))
set_exec_queue_wedged(q);
mutex_unlock(&guc->submission_state.lock);
} else {
/* Forcefully kill any remaining exec queues, signal fences */
guc_submit_reset_prepare(guc);
xe_guc_submit_stop(guc);
xe_guc_softreset(guc);
xe_uc_fw_sanitize(&guc->fw);
xe_guc_submit_pause_abort(guc);
}
}
static bool guc_submit_hint_wedged(struct xe_guc *guc)
{
struct xe_device *xe = guc_to_xe(guc);
if (xe->wedged.mode != XE_WEDGED_MODE_UPON_ANY_HANG_NO_RESET)
return false;
if (xe_device_wedged(xe))
return true;
xe_device_declare_wedged(xe);
return true;
}
#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)
{
struct xe_gt *gt = guc_to_gt(exec_queue_to_guc(q));
u32 ctx_timestamp, ctx_job_timestamp;
u32 timeout_ms = q->sched_props.job_timeout_ms;
u32 diff;
u64 running_time_ms;
if (!xe_sched_job_started(job)) {
xe_gt_warn(gt, "Check job timeout: seqno=%u, lrc_seqno=%u, guc_id=%d, not started",
xe_sched_job_seqno(job), xe_sched_job_lrc_seqno(job),
q->guc->id);
return xe_sched_invalidate_job(job, 2);
}
ctx_timestamp = lower_32_bits(xe_lrc_timestamp(q->lrc[0]));
if (ctx_timestamp == job->sample_timestamp) {
if (IS_SRIOV_VF(gt_to_xe(gt)))
xe_gt_notice(gt, "Check job timeout: seqno=%u, lrc_seqno=%u, guc_id=%d, timestamp stuck",
xe_sched_job_seqno(job),
xe_sched_job_lrc_seqno(job), q->guc->id);
else
xe_gt_warn(gt, "Check job timeout: seqno=%u, lrc_seqno=%u, guc_id=%d, timestamp stuck",
xe_sched_job_seqno(job),
xe_sched_job_lrc_seqno(job), q->guc->id);
return xe_sched_invalidate_job(job, 0);
}
job->sample_timestamp = ctx_timestamp;
ctx_job_timestamp = xe_lrc_ctx_job_timestamp(q->lrc[0]);
/*
* Counter wraps at ~223s at the usual 19.2MHz, be paranoid catch
* possible overflows with a high timeout.
*/
xe_gt_assert(gt, timeout_ms < 100 * MSEC_PER_SEC);
diff = ctx_timestamp - ctx_job_timestamp;
/*
* Ensure timeout is within 5% to account for an GuC scheduling latency
*/
running_time_ms =
ADJUST_FIVE_PERCENT(xe_gt_clock_interval_to_ms(gt, diff));
xe_gt_dbg(gt,
"Check job timeout: seqno=%u, lrc_seqno=%u, guc_id=%d, running_time_ms=%llu, timeout_ms=%u, diff=0x%08x",
xe_sched_job_seqno(job), xe_sched_job_lrc_seqno(job),
q->guc->id, running_time_ms, timeout_ms, diff);
return running_time_ms >= timeout_ms;
}
static void enable_scheduling(struct xe_exec_queue *q)
{
MAKE_SCHED_CONTEXT_ACTION(q, ENABLE);
struct xe_guc *guc = exec_queue_to_guc(q);
int ret;
xe_gt_assert(guc_to_gt(guc), !exec_queue_destroyed(q));
xe_gt_assert(guc_to_gt(guc), exec_queue_registered(q));
xe_gt_assert(guc_to_gt(guc), !exec_queue_pending_disable(q));
xe_gt_assert(guc_to_gt(guc), !exec_queue_pending_enable(q));
set_exec_queue_pending_enable(q);
set_exec_queue_enabled(q);
trace_xe_exec_queue_scheduling_enable(q);
if (xe_exec_queue_is_multi_queue_secondary(q))
handle_multi_queue_secondary_sched_done(guc, q, 1);
else
xe_guc_ct_send(&guc->ct, action, ARRAY_SIZE(action),
G2H_LEN_DW_SCHED_CONTEXT_MODE_SET, 1);
ret = wait_event_timeout(guc->ct.wq,
!exec_queue_pending_enable(q) ||
xe_guc_read_stopped(guc) ||
vf_recovery(guc), HZ * 5);
if ((!ret && !vf_recovery(guc)) || xe_guc_read_stopped(guc)) {
xe_gt_warn(guc_to_gt(guc), "Schedule enable failed to respond");
set_exec_queue_banned(q);
xe_gt_reset_async(q->gt);
xe_sched_tdr_queue_imm(&q->guc->sched);
}
}
static void disable_scheduling(struct xe_exec_queue *q, bool immediate)
{
MAKE_SCHED_CONTEXT_ACTION(q, DISABLE);
struct xe_guc *guc = exec_queue_to_guc(q);
xe_gt_assert(guc_to_gt(guc), !exec_queue_destroyed(q));
xe_gt_assert(guc_to_gt(guc), exec_queue_registered(q));
xe_gt_assert(guc_to_gt(guc), !exec_queue_pending_disable(q));
if (immediate && !xe_exec_queue_is_multi_queue_secondary(q))
set_min_preemption_timeout(guc, q);
clear_exec_queue_enabled(q);
set_exec_queue_pending_disable(q);
trace_xe_exec_queue_scheduling_disable(q);
if (xe_exec_queue_is_multi_queue_secondary(q))
handle_multi_queue_secondary_sched_done(guc, q, 0);
else
xe_guc_ct_send(&guc->ct, action, ARRAY_SIZE(action),
G2H_LEN_DW_SCHED_CONTEXT_MODE_SET, 1);
}
static enum drm_gpu_sched_stat
guc_exec_queue_timedout_job(struct drm_sched_job *drm_job)
{
struct xe_sched_job *job = to_xe_sched_job(drm_job);
struct drm_sched_job *tmp_job;
struct xe_exec_queue *q = job->q;
struct xe_gpu_scheduler *sched = &q->guc->sched;
struct xe_guc *guc = exec_queue_to_guc(q);
const char *process_name = "no process";
struct xe_device *xe = guc_to_xe(guc);
int err = -ETIME;
pid_t pid = -1;
bool wedged = false, skip_timeout_check;
xe_gt_assert(guc_to_gt(guc), !exec_queue_destroyed(q));
/*
* TDR has fired before free job worker. Common if exec queue
* immediately closed after last fence signaled. Add back to pending
* list so job can be freed and kick scheduler ensuring free job is not
* lost.
*/
if (test_bit(DMA_FENCE_FLAG_SIGNALED_BIT, &job->fence->flags) ||
vf_recovery(guc))
return DRM_GPU_SCHED_STAT_NO_HANG;
/* Kill the run_job entry point */
xe_sched_submission_stop(sched);
/* Must check all state after stopping scheduler */
skip_timeout_check = exec_queue_reset(q) ||
exec_queue_killed_or_banned_or_wedged(q);
/* Skip timeout check if multi-queue group is banned */
if (xe_exec_queue_is_multi_queue(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
* possible memory corruptions. This means disabling scheduling on the
* primary queue before or during the secondary queue's TDR. Need to
* implement this in least obtrusive way.
*/
/*
* If devcoredump not captured and GuC capture for the job is not ready
* do manual capture first and decide later if we need to use it
*/
if (!exec_queue_killed(q) && !xe->devcoredump.captured &&
!xe_guc_capture_get_matching_and_lock(q)) {
/* take force wake before engine register manual capture */
CLASS(xe_force_wake, fw_ref)(gt_to_fw(q->gt), XE_FORCEWAKE_ALL);
if (!xe_force_wake_ref_has_domain(fw_ref.domains, XE_FORCEWAKE_ALL))
xe_gt_info(q->gt, "failed to get forcewake for coredump capture\n");
xe_engine_snapshot_capture_for_queue(q);
}
/*
* Check if job is actually timed out, if so restart job execution and TDR
*/
if (!skip_timeout_check && !check_timeout(q, job))
goto rearm;
if (!exec_queue_killed(q))
wedged = guc_submit_hint_wedged(exec_queue_to_guc(q));
set_exec_queue_banned(q);
/* Kick job / queue off hardware */
if (!wedged && (exec_queue_enabled(q) || exec_queue_pending_disable(q))) {
int ret;
if (exec_queue_reset(q))
err = -EIO;
if (xe_uc_fw_is_running(&guc->fw)) {
/*
* Wait for any pending G2H to flush out before
* modifying state
*/
ret = wait_event_timeout(guc->ct.wq,
(!exec_queue_pending_enable(q) &&
!exec_queue_pending_disable(q)) ||
xe_guc_read_stopped(guc) ||
vf_recovery(guc), HZ * 5);
if (vf_recovery(guc))
goto handle_vf_resume;
if (!ret || xe_guc_read_stopped(guc))
goto trigger_reset;
disable_scheduling(q, skip_timeout_check);
}
/*
* Must wait for scheduling to be disabled before signalling
* any fences, if GT broken the GT reset code should signal us.
*
* FIXME: Tests can generate a ton of 0x6000 (IOMMU CAT fault
* error) messages which can cause the schedule disable to get
* lost. If this occurs, trigger a GT reset to recover.
*/
smp_rmb();
ret = wait_event_timeout(guc->ct.wq,
!xe_uc_fw_is_running(&guc->fw) ||
!exec_queue_pending_disable(q) ||
xe_guc_read_stopped(guc) ||
vf_recovery(guc), HZ * 5);
if (vf_recovery(guc))
goto handle_vf_resume;
if (!ret || xe_guc_read_stopped(guc)) {
trigger_reset:
if (!ret)
xe_gt_warn(guc_to_gt(guc),
"Schedule disable failed to respond, guc_id=%d",
q->guc->id);
xe_devcoredump(q, job,
"Schedule disable failed to respond, guc_id=%d, ret=%d, guc_read=%d",
q->guc->id, ret, xe_guc_read_stopped(guc));
xe_gt_reset_async(q->gt);
xe_sched_tdr_queue_imm(sched);
goto rearm;
}
}
if (q->vm && q->vm->xef) {
process_name = q->vm->xef->process_name;
pid = q->vm->xef->pid;
}
if (!exec_queue_killed(q))
xe_gt_notice(guc_to_gt(guc),
"Timedout job: seqno=%u, lrc_seqno=%u, guc_id=%d, flags=0x%lx in %s [%d]",
xe_sched_job_seqno(job), xe_sched_job_lrc_seqno(job),
q->guc->id, q->flags, process_name, pid);
trace_xe_sched_job_timedout(job);
if (!exec_queue_killed(q))
xe_devcoredump(q, job,
"Timedout job - seqno=%u, lrc_seqno=%u, guc_id=%d, flags=0x%lx",
xe_sched_job_seqno(job), xe_sched_job_lrc_seqno(job),
q->guc->id, q->flags);
/*
* Kernel jobs should never fail, nor should VM jobs if they do
* somethings has gone wrong and the GT needs a reset
*/
xe_gt_WARN(q->gt, q->flags & EXEC_QUEUE_FLAG_KERNEL,
"Kernel-submitted job timed out\n");
xe_gt_WARN(q->gt, q->flags & EXEC_QUEUE_FLAG_VM && !exec_queue_killed(q),
"VM job timed out on non-killed execqueue\n");
if (!wedged && (q->flags & EXEC_QUEUE_FLAG_KERNEL ||
(q->flags & EXEC_QUEUE_FLAG_VM && !exec_queue_killed(q)))) {
if (!xe_sched_invalidate_job(job, 2)) {
xe_gt_reset_async(q->gt);
goto rearm;
}
}
/* Mark all outstanding jobs as bad, thus completing them */
xe_sched_job_set_error(job, err);
drm_sched_for_each_pending_job(tmp_job, &sched->base, NULL)
xe_sched_job_set_error(to_xe_sched_job(tmp_job), -ECANCELED);
xe_sched_submission_start(sched);
if (xe_exec_queue_is_multi_queue(q))
xe_guc_exec_queue_group_trigger_cleanup(q);
else
xe_guc_exec_queue_trigger_cleanup(q);
/*
* We want the job added back to the pending list so it gets freed; this
* is what DRM_GPU_SCHED_STAT_NO_HANG does.
*/
return DRM_GPU_SCHED_STAT_NO_HANG;
rearm:
/*
* XXX: Ideally want to adjust timeout based on current execution time
* but there is not currently an easy way to do in DRM scheduler. With
* some thought, do this in a follow up.
*/
xe_sched_submission_start(sched);
handle_vf_resume:
return DRM_GPU_SCHED_STAT_NO_HANG;
}
static void guc_exec_queue_fini(struct xe_exec_queue *q)
{
struct xe_guc_exec_queue *ge = q->guc;
struct xe_guc *guc = exec_queue_to_guc(q);
release_guc_id(guc, q);
xe_sched_entity_fini(&ge->entity);
xe_sched_fini(&ge->sched);
/*
* RCU free due sched being exported via DRM scheduler fences
* (timeline name).
*/
kfree_rcu(ge, rcu);
}
static void __guc_exec_queue_destroy_async(struct work_struct *w)
{
struct xe_guc_exec_queue *ge =
container_of(w, struct xe_guc_exec_queue, destroy_async);
struct xe_exec_queue *q = ge->q;
struct xe_guc *guc = exec_queue_to_guc(q);
guard(xe_pm_runtime)(guc_to_xe(guc));
trace_xe_exec_queue_destroy(q);
if (xe_exec_queue_is_multi_queue_secondary(q)) {
struct xe_exec_queue_group *group = q->multi_queue.group;
mutex_lock(&group->list_lock);
list_del(&q->multi_queue.link);
mutex_unlock(&group->list_lock);
}
/* Confirm no work left behind accessing device structures */
cancel_delayed_work_sync(&ge->sched.base.work_tdr);
xe_exec_queue_fini(q);
}
static void guc_exec_queue_destroy_async(struct xe_exec_queue *q)
{
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_device *xe = guc_to_xe(guc);
INIT_WORK(&q->guc->destroy_async, __guc_exec_queue_destroy_async);
/* We must block on kernel engines so slabs are empty on driver unload */
if (q->flags & EXEC_QUEUE_FLAG_PERMANENT || exec_queue_wedged(q))
__guc_exec_queue_destroy_async(&q->guc->destroy_async);
else
queue_work(xe->destroy_wq, &q->guc->destroy_async);
}
static void __guc_exec_queue_destroy(struct xe_guc *guc, struct xe_exec_queue *q)
{
/*
* Might be done from within the GPU scheduler, need to do async as we
* fini the scheduler when the engine is fini'd, the scheduler can't
* complete fini within itself (circular dependency). Async resolves
* this we and don't really care when everything is fini'd, just that it
* is.
*/
guc_exec_queue_destroy_async(q);
}
static void __guc_exec_queue_process_msg_cleanup(struct xe_sched_msg *msg)
{
struct xe_exec_queue *q = msg->private_data;
struct xe_guc *guc = exec_queue_to_guc(q);
xe_gt_assert(guc_to_gt(guc), !(q->flags & EXEC_QUEUE_FLAG_PERMANENT));
trace_xe_exec_queue_cleanup_entity(q);
/*
* Expected state transitions for cleanup:
* - If the exec queue is registered and GuC firmware is running, we must first
* disable scheduling and deregister the queue to ensure proper teardown and
* resource release in the GuC, then destroy the exec queue on driver side.
* - If the GuC is already stopped (e.g., during driver unload or GPU reset),
* we cannot expect a response for the deregister request. In this case,
* it is safe to directly destroy the exec queue on driver side, as the GuC
* will not process further requests and all resources must be cleaned up locally.
*/
if (exec_queue_registered(q) && xe_uc_fw_is_running(&guc->fw))
disable_scheduling_deregister(guc, q);
else
__guc_exec_queue_destroy(guc, q);
}
static bool guc_exec_queue_allowed_to_change_state(struct xe_exec_queue *q)
{
return !exec_queue_killed_or_banned_or_wedged(q) && exec_queue_registered(q);
}
static void __guc_exec_queue_process_msg_set_sched_props(struct xe_sched_msg *msg)
{
struct xe_exec_queue *q = msg->private_data;
struct xe_guc *guc = exec_queue_to_guc(q);
if (guc_exec_queue_allowed_to_change_state(q))
init_policies(guc, q);
kfree(msg);
}
static void __suspend_fence_signal(struct xe_exec_queue *q)
{
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_device *xe = guc_to_xe(guc);
if (!q->guc->suspend_pending)
return;
WRITE_ONCE(q->guc->suspend_pending, false);
/*
* We use a GuC shared wait queue for VFs because the VF resfix start
* interrupt must be able to wake all instances of suspend_wait. This
* prevents the VF migration worker from being starved during
* scheduling.
*/
if (IS_SRIOV_VF(xe))
wake_up_all(&guc->ct.wq);
else
wake_up(&q->guc->suspend_wait);
}
static void suspend_fence_signal(struct xe_exec_queue *q)
{
struct xe_guc *guc = exec_queue_to_guc(q);
xe_gt_assert(guc_to_gt(guc), exec_queue_suspended(q) || exec_queue_killed(q) ||
xe_guc_read_stopped(guc));
xe_gt_assert(guc_to_gt(guc), q->guc->suspend_pending);
__suspend_fence_signal(q);
}
static void __guc_exec_queue_process_msg_suspend(struct xe_sched_msg *msg)
{
struct xe_exec_queue *q = msg->private_data;
struct xe_guc *guc = exec_queue_to_guc(q);
bool idle_skip_suspend = xe_exec_queue_idle_skip_suspend(q);
if (!idle_skip_suspend && guc_exec_queue_allowed_to_change_state(q) &&
!exec_queue_suspended(q) && exec_queue_enabled(q)) {
wait_event(guc->ct.wq, vf_recovery(guc) ||
((q->guc->resume_time != RESUME_PENDING ||
xe_guc_read_stopped(guc)) && !exec_queue_pending_disable(q)));
if (!xe_guc_read_stopped(guc)) {
s64 since_resume_ms =
ktime_ms_delta(ktime_get(),
q->guc->resume_time);
s64 wait_ms = q->vm->preempt.min_run_period_ms -
since_resume_ms;
if (wait_ms > 0 && q->guc->resume_time)
relaxed_ms_sleep(wait_ms);
set_exec_queue_suspended(q);
disable_scheduling(q, false);
}
} else if (q->guc->suspend_pending) {
if (idle_skip_suspend)
set_exec_queue_idle_skip_suspend(q);
set_exec_queue_suspended(q);
suspend_fence_signal(q);
}
}
static void sched_context(struct xe_exec_queue *q)
{
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_lrc *lrc = q->lrc[0];
u32 action[] = {
XE_GUC_ACTION_SCHED_CONTEXT,
q->guc->id,
};
xe_gt_assert(guc_to_gt(guc), !xe_exec_queue_is_parallel(q));
xe_gt_assert(guc_to_gt(guc), !exec_queue_destroyed(q));
xe_gt_assert(guc_to_gt(guc), exec_queue_registered(q));
xe_gt_assert(guc_to_gt(guc), !exec_queue_pending_disable(q));
trace_xe_exec_queue_submit(q);
xe_lrc_set_ring_tail(lrc, lrc->ring.tail);
xe_guc_ct_send(&guc->ct, action, ARRAY_SIZE(action), 0, 0);
}
static void __guc_exec_queue_process_msg_resume(struct xe_sched_msg *msg)
{
struct xe_exec_queue *q = msg->private_data;
if (guc_exec_queue_allowed_to_change_state(q)) {
clear_exec_queue_suspended(q);
if (!exec_queue_enabled(q)) {
if (exec_queue_idle_skip_suspend(q)) {
struct xe_lrc *lrc = q->lrc[0];
clear_exec_queue_idle_skip_suspend(q);
xe_lrc_set_ring_tail(lrc, lrc->ring.tail);
}
q->guc->resume_time = RESUME_PENDING;
set_exec_queue_pending_resume(q);
enable_scheduling(q);
} else if (exec_queue_idle_skip_suspend(q)) {
clear_exec_queue_idle_skip_suspend(q);
sched_context(q);
}
} else {
clear_exec_queue_suspended(q);
clear_exec_queue_idle_skip_suspend(q);
}
}
static void __guc_exec_queue_process_msg_set_multi_queue_priority(struct xe_sched_msg *msg)
{
struct xe_exec_queue *q = msg->private_data;
if (guc_exec_queue_allowed_to_change_state(q)) {
#define MAX_MULTI_QUEUE_CGP_SYNC_SIZE (2)
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_exec_queue_group *group = q->multi_queue.group;
u32 action[MAX_MULTI_QUEUE_CGP_SYNC_SIZE];
int len = 0;
action[len++] = XE_GUC_ACTION_MULTI_QUEUE_CONTEXT_CGP_SYNC;
action[len++] = group->primary->guc->id;
xe_gt_assert(guc_to_gt(guc), len <= MAX_MULTI_QUEUE_CGP_SYNC_SIZE);
#undef MAX_MULTI_QUEUE_CGP_SYNC_SIZE
xe_guc_exec_queue_group_cgp_sync(guc, q, action, len);
}
kfree(msg);
}
#define CLEANUP 1 /* Non-zero values to catch uninitialized msg */
#define SET_SCHED_PROPS 2
#define SUSPEND 3
#define RESUME 4
#define SET_MULTI_QUEUE_PRIORITY 5
#define OPCODE_MASK 0xf
#define MSG_LOCKED BIT(8)
#define MSG_HEAD BIT(9)
static void guc_exec_queue_process_msg(struct xe_sched_msg *msg)
{
struct xe_device *xe = guc_to_xe(exec_queue_to_guc(msg->private_data));
trace_xe_sched_msg_recv(msg);
switch (msg->opcode) {
case CLEANUP:
__guc_exec_queue_process_msg_cleanup(msg);
break;
case SET_SCHED_PROPS:
__guc_exec_queue_process_msg_set_sched_props(msg);
break;
case SUSPEND:
__guc_exec_queue_process_msg_suspend(msg);
break;
case RESUME:
__guc_exec_queue_process_msg_resume(msg);
break;
case SET_MULTI_QUEUE_PRIORITY:
__guc_exec_queue_process_msg_set_multi_queue_priority(msg);
break;
default:
XE_WARN_ON("Unknown message type");
}
xe_pm_runtime_put(xe);
}
static const struct drm_sched_backend_ops drm_sched_ops = {
.run_job = guc_exec_queue_run_job,
.free_job = guc_exec_queue_free_job,
.timedout_job = guc_exec_queue_timedout_job,
};
static const struct xe_sched_backend_ops xe_sched_ops = {
.process_msg = guc_exec_queue_process_msg,
};
static int guc_exec_queue_init(struct xe_exec_queue *q)
{
struct xe_gpu_scheduler *sched;
struct xe_guc *guc = exec_queue_to_guc(q);
struct workqueue_struct *submit_wq = NULL;
struct xe_guc_exec_queue *ge;
long timeout;
int err, i;
xe_gt_assert(guc_to_gt(guc), xe_device_uc_enabled(guc_to_xe(guc)));
ge = kzalloc_obj(*ge);
if (!ge)
return -ENOMEM;
q->guc = ge;
ge->q = q;
init_rcu_head(&ge->rcu);
init_waitqueue_head(&ge->suspend_wait);
for (i = 0; i < MAX_STATIC_MSG_TYPE; ++i)
INIT_LIST_HEAD(&ge->static_msgs[i].link);
timeout = (q->vm && xe_vm_in_lr_mode(q->vm)) ? MAX_SCHEDULE_TIMEOUT :
msecs_to_jiffies(q->sched_props.job_timeout_ms);
/*
* Use primary queue's submit_wq for all secondary queues of a
* multi queue group. This serialization avoids any locking around
* CGP synchronization with GuC.
*/
if (xe_exec_queue_is_multi_queue_secondary(q)) {
struct xe_exec_queue *primary = xe_exec_queue_multi_queue_primary(q);
submit_wq = primary->guc->sched.base.submit_wq;
}
err = xe_sched_init(&ge->sched, &drm_sched_ops, &xe_sched_ops,
submit_wq, xe_lrc_ring_size() / MAX_JOB_SIZE_BYTES, 64,
timeout, guc_to_gt(guc)->ordered_wq, NULL,
q->name, gt_to_xe(q->gt)->drm.dev);
if (err)
goto err_free;
sched = &ge->sched;
err = xe_sched_entity_init(&ge->entity, sched);
if (err)
goto err_sched;
mutex_lock(&guc->submission_state.lock);
err = alloc_guc_id(guc, q);
if (err)
goto err_entity;
q->entity = &ge->entity;
if (xe_guc_read_stopped(guc) || vf_recovery(guc))
xe_sched_stop(sched);
mutex_unlock(&guc->submission_state.lock);
xe_exec_queue_assign_name(q, q->guc->id);
/*
* Maintain secondary queues of the multi queue group in a list
* for handling dependencies across the queues in the group.
*/
if (xe_exec_queue_is_multi_queue_secondary(q)) {
struct xe_exec_queue_group *group = q->multi_queue.group;
INIT_LIST_HEAD(&q->multi_queue.link);
mutex_lock(&group->list_lock);
list_add_tail(&q->multi_queue.link, &group->list);
mutex_unlock(&group->list_lock);
}
if (xe_exec_queue_is_multi_queue(q))
trace_xe_exec_queue_create_multi_queue(q);
else
trace_xe_exec_queue_create(q);
return 0;
err_entity:
mutex_unlock(&guc->submission_state.lock);
xe_sched_entity_fini(&ge->entity);
err_sched:
xe_sched_fini(&ge->sched);
err_free:
kfree(ge);
return err;
}
static void guc_exec_queue_kill(struct xe_exec_queue *q)
{
trace_xe_exec_queue_kill(q);
set_exec_queue_killed(q);
__suspend_fence_signal(q);
xe_guc_exec_queue_trigger_cleanup(q);
}
static void guc_exec_queue_add_msg(struct xe_exec_queue *q, struct xe_sched_msg *msg,
u32 opcode)
{
xe_pm_runtime_get_noresume(guc_to_xe(exec_queue_to_guc(q)));
INIT_LIST_HEAD(&msg->link);
msg->opcode = opcode & OPCODE_MASK;
msg->private_data = q;
trace_xe_sched_msg_add(msg);
if (opcode & MSG_HEAD)
xe_sched_add_msg_head(&q->guc->sched, msg);
else if (opcode & MSG_LOCKED)
xe_sched_add_msg_locked(&q->guc->sched, msg);
else
xe_sched_add_msg(&q->guc->sched, msg);
}
static void guc_exec_queue_try_add_msg_head(struct xe_exec_queue *q,
struct xe_sched_msg *msg,
u32 opcode)
{
if (!list_empty(&msg->link))
return;
guc_exec_queue_add_msg(q, msg, opcode | MSG_LOCKED | MSG_HEAD);
}
static bool guc_exec_queue_try_add_msg(struct xe_exec_queue *q,
struct xe_sched_msg *msg,
u32 opcode)
{
if (!list_empty(&msg->link))
return false;
guc_exec_queue_add_msg(q, msg, opcode | MSG_LOCKED);
return true;
}
#define STATIC_MSG_CLEANUP 0
#define STATIC_MSG_SUSPEND 1
#define STATIC_MSG_RESUME 2
static void guc_exec_queue_destroy(struct xe_exec_queue *q)
{
struct xe_sched_msg *msg = q->guc->static_msgs + STATIC_MSG_CLEANUP;
if (!(q->flags & EXEC_QUEUE_FLAG_PERMANENT) && !exec_queue_wedged(q))
guc_exec_queue_add_msg(q, msg, CLEANUP);
else
__guc_exec_queue_destroy(exec_queue_to_guc(q), q);
}
static int guc_exec_queue_set_priority(struct xe_exec_queue *q,
enum xe_exec_queue_priority priority)
{
struct xe_sched_msg *msg;
if (q->sched_props.priority == priority ||
exec_queue_killed_or_banned_or_wedged(q))
return 0;
msg = kmalloc_obj(*msg);
if (!msg)
return -ENOMEM;
q->sched_props.priority = priority;
guc_exec_queue_add_msg(q, msg, SET_SCHED_PROPS);
return 0;
}
static int guc_exec_queue_set_timeslice(struct xe_exec_queue *q, u32 timeslice_us)
{
struct xe_sched_msg *msg;
if (q->sched_props.timeslice_us == timeslice_us ||
exec_queue_killed_or_banned_or_wedged(q))
return 0;
msg = kmalloc_obj(*msg);
if (!msg)
return -ENOMEM;
q->sched_props.timeslice_us = timeslice_us;
guc_exec_queue_add_msg(q, msg, SET_SCHED_PROPS);
return 0;
}
static int guc_exec_queue_set_preempt_timeout(struct xe_exec_queue *q,
u32 preempt_timeout_us)
{
struct xe_sched_msg *msg;
if (q->sched_props.preempt_timeout_us == preempt_timeout_us ||
exec_queue_killed_or_banned_or_wedged(q))
return 0;
msg = kmalloc_obj(*msg);
if (!msg)
return -ENOMEM;
q->sched_props.preempt_timeout_us = preempt_timeout_us;
guc_exec_queue_add_msg(q, msg, SET_SCHED_PROPS);
return 0;
}
static int guc_exec_queue_set_multi_queue_priority(struct xe_exec_queue *q,
enum xe_multi_queue_priority priority)
{
struct xe_sched_msg *msg;
xe_gt_assert(guc_to_gt(exec_queue_to_guc(q)), xe_exec_queue_is_multi_queue(q));
if (q->multi_queue.priority == priority ||
exec_queue_killed_or_banned_or_wedged(q))
return 0;
msg = kmalloc_obj(*msg);
if (!msg)
return -ENOMEM;
q->multi_queue.priority = priority;
guc_exec_queue_add_msg(q, msg, SET_MULTI_QUEUE_PRIORITY);
return 0;
}
static int guc_exec_queue_suspend(struct xe_exec_queue *q)
{
struct xe_gpu_scheduler *sched = &q->guc->sched;
struct xe_sched_msg *msg = q->guc->static_msgs + STATIC_MSG_SUSPEND;
if (exec_queue_killed_or_banned_or_wedged(q))
return -EINVAL;
xe_sched_msg_lock(sched);
if (guc_exec_queue_try_add_msg(q, msg, SUSPEND))
q->guc->suspend_pending = true;
xe_sched_msg_unlock(sched);
return 0;
}
static int guc_exec_queue_suspend_wait(struct xe_exec_queue *q)
{
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_device *xe = guc_to_xe(guc);
int ret;
/*
* Likely don't need to check exec_queue_killed() as we clear
* suspend_pending upon kill but to be paranoid but races in which
* suspend_pending is set after kill also check kill here.
*/
#define WAIT_COND \
(!READ_ONCE(q->guc->suspend_pending) || exec_queue_killed(q) || \
xe_guc_read_stopped(guc))
retry:
if (IS_SRIOV_VF(xe))
ret = wait_event_interruptible_timeout(guc->ct.wq, WAIT_COND ||
vf_recovery(guc),
HZ * 5);
else
ret = wait_event_interruptible_timeout(q->guc->suspend_wait,
WAIT_COND, HZ * 5);
if (vf_recovery(guc) && !xe_device_wedged((guc_to_xe(guc))))
return -EAGAIN;
if (!ret) {
xe_gt_warn(guc_to_gt(guc),
"Suspend fence, guc_id=%d, failed to respond",
q->guc->id);
/* XXX: Trigger GT reset? */
return -ETIME;
} else if (IS_SRIOV_VF(xe) && !WAIT_COND) {
/* Corner case on RESFIX DONE where vf_recovery() changes */
goto retry;
}
#undef WAIT_COND
return ret < 0 ? ret : 0;
}
static void guc_exec_queue_resume(struct xe_exec_queue *q)
{
struct xe_gpu_scheduler *sched = &q->guc->sched;
struct xe_sched_msg *msg = q->guc->static_msgs + STATIC_MSG_RESUME;
struct xe_guc *guc = exec_queue_to_guc(q);
xe_gt_assert(guc_to_gt(guc), !q->guc->suspend_pending);
xe_sched_msg_lock(sched);
guc_exec_queue_try_add_msg(q, msg, RESUME);
xe_sched_msg_unlock(sched);
}
static bool guc_exec_queue_reset_status(struct xe_exec_queue *q)
{
if (xe_exec_queue_is_multi_queue_secondary(q) &&
guc_exec_queue_reset_status(xe_exec_queue_multi_queue_primary(q)))
return true;
return exec_queue_reset(q) || exec_queue_killed_or_banned_or_wedged(q);
}
/*
* All of these functions are an abstraction layer which other parts of Xe can
* use to trap into the GuC backend. All of these functions, aside from init,
* really shouldn't do much other than trap into the DRM scheduler which
* synchronizes these operations.
*/
static const struct xe_exec_queue_ops guc_exec_queue_ops = {
.init = guc_exec_queue_init,
.kill = guc_exec_queue_kill,
.fini = guc_exec_queue_fini,
.destroy = guc_exec_queue_destroy,
.set_priority = guc_exec_queue_set_priority,
.set_timeslice = guc_exec_queue_set_timeslice,
.set_preempt_timeout = guc_exec_queue_set_preempt_timeout,
.set_multi_queue_priority = guc_exec_queue_set_multi_queue_priority,
.suspend = guc_exec_queue_suspend,
.suspend_wait = guc_exec_queue_suspend_wait,
.resume = guc_exec_queue_resume,
.reset_status = guc_exec_queue_reset_status,
};
static void guc_exec_queue_stop(struct xe_guc *guc, struct xe_exec_queue *q)
{
struct xe_gpu_scheduler *sched = &q->guc->sched;
bool do_destroy = false;
/* Stop scheduling + flush any DRM scheduler operations */
xe_sched_submission_stop(sched);
/* Clean up lost G2H + reset engine state */
if (exec_queue_registered(q)) {
if (exec_queue_destroyed(q))
do_destroy = true;
}
if (q->guc->suspend_pending) {
set_exec_queue_suspended(q);
suspend_fence_signal(q);
}
atomic_and(EXEC_QUEUE_STATE_WEDGED | EXEC_QUEUE_STATE_BANNED |
EXEC_QUEUE_STATE_KILLED | EXEC_QUEUE_STATE_DESTROYED |
EXEC_QUEUE_STATE_SUSPENDED,
&q->guc->state);
q->guc->resume_time = 0;
trace_xe_exec_queue_stop(q);
/*
* Ban any engine (aside from kernel and engines used for VM ops) with a
* started but not complete job or if a job has gone through a GT reset
* more than twice.
*/
if (!(q->flags & (EXEC_QUEUE_FLAG_KERNEL | EXEC_QUEUE_FLAG_VM))) {
struct xe_sched_job *job = xe_sched_first_pending_job(sched);
bool ban = false;
if (job) {
if ((xe_sched_job_started(job) &&
!xe_sched_job_completed(job)) ||
xe_sched_invalidate_job(job, 2)) {
trace_xe_sched_job_ban(job);
ban = true;
}
}
if (ban) {
set_exec_queue_banned(q);
xe_guc_exec_queue_trigger_cleanup(q);
}
}
if (do_destroy)
__guc_exec_queue_destroy(guc, q);
}
static int guc_submit_reset_prepare(struct xe_guc *guc)
{
int ret;
/*
* Using an atomic here rather than submission_state.lock as this
* function can be called while holding the CT lock (engine reset
* failure). submission_state.lock needs the CT lock to resubmit jobs.
* Atomic is not ideal, but it works to prevent against concurrent reset
* and releasing any TDRs waiting on guc->submission_state.stopped.
*/
ret = atomic_fetch_or(1, &guc->submission_state.stopped);
smp_wmb();
wake_up_all(&guc->ct.wq);
return ret;
}
int xe_guc_submit_reset_prepare(struct xe_guc *guc)
{
if (xe_gt_WARN_ON(guc_to_gt(guc), vf_recovery(guc)))
return 0;
if (!guc->submission_state.initialized)
return 0;
return guc_submit_reset_prepare(guc);
}
void xe_guc_submit_reset_wait(struct xe_guc *guc)
{
wait_event(guc->ct.wq, xe_device_wedged(guc_to_xe(guc)) ||
!xe_guc_read_stopped(guc));
}
void xe_guc_submit_stop(struct xe_guc *guc)
{
struct xe_exec_queue *q;
unsigned long index;
xe_gt_assert(guc_to_gt(guc), xe_guc_read_stopped(guc) == 1);
mutex_lock(&guc->submission_state.lock);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q) {
/* Prevent redundant attempts to stop parallel queues */
if (q->guc->id != index)
continue;
guc_exec_queue_stop(guc, q);
}
mutex_unlock(&guc->submission_state.lock);
/*
* No one can enter the backend at this point, aside from new engine
* creation which is protected by guc->submission_state.lock.
*/
}
static void guc_exec_queue_revert_pending_state_change(struct xe_guc *guc,
struct xe_exec_queue *q)
{
bool pending_enable, pending_disable, pending_resume;
pending_enable = exec_queue_pending_enable(q);
pending_resume = exec_queue_pending_resume(q);
if (pending_enable && pending_resume) {
q->guc->needs_resume = true;
xe_gt_dbg(guc_to_gt(guc), "Replay RESUME - guc_id=%d",
q->guc->id);
}
if (pending_enable && !pending_resume) {
clear_exec_queue_registered(q);
xe_gt_dbg(guc_to_gt(guc), "Replay REGISTER - guc_id=%d",
q->guc->id);
}
if (pending_enable) {
clear_exec_queue_enabled(q);
clear_exec_queue_pending_resume(q);
clear_exec_queue_pending_enable(q);
xe_gt_dbg(guc_to_gt(guc), "Replay ENABLE - guc_id=%d",
q->guc->id);
}
if (exec_queue_destroyed(q) && exec_queue_registered(q)) {
clear_exec_queue_destroyed(q);
q->guc->needs_cleanup = true;
xe_gt_dbg(guc_to_gt(guc), "Replay CLEANUP - guc_id=%d",
q->guc->id);
}
pending_disable = exec_queue_pending_disable(q);
if (pending_disable && exec_queue_suspended(q)) {
clear_exec_queue_suspended(q);
q->guc->needs_suspend = true;
xe_gt_dbg(guc_to_gt(guc), "Replay SUSPEND - guc_id=%d",
q->guc->id);
}
if (pending_disable) {
if (!pending_enable)
set_exec_queue_enabled(q);
clear_exec_queue_pending_disable(q);
xe_gt_dbg(guc_to_gt(guc), "Replay DISABLE - guc_id=%d",
q->guc->id);
}
q->guc->resume_time = 0;
}
static void lrc_parallel_clear(struct xe_lrc *lrc)
{
struct xe_device *xe = gt_to_xe(lrc->gt);
struct iosys_map map = xe_lrc_parallel_map(lrc);
int i;
for (i = 0; i < WQ_SIZE / sizeof(u32); ++i)
parallel_write(xe, map, wq[i],
FIELD_PREP(WQ_TYPE_MASK, WQ_TYPE_NOOP) |
FIELD_PREP(WQ_LEN_MASK, 0));
}
/*
* This function is quite complex but only real way to ensure no state is lost
* during VF resume flows. The function scans the queue state, make adjustments
* as needed, and queues jobs / messages which replayed upon unpause.
*/
static void guc_exec_queue_pause(struct xe_guc *guc, struct xe_exec_queue *q)
{
struct xe_gpu_scheduler *sched = &q->guc->sched;
struct xe_sched_job *job;
int i;
lockdep_assert_held(&guc->submission_state.lock);
/* Stop scheduling + flush any DRM scheduler operations */
xe_sched_submission_stop(sched);
cancel_delayed_work_sync(&sched->base.work_tdr);
guc_exec_queue_revert_pending_state_change(guc, q);
if (xe_exec_queue_is_parallel(q)) {
/* Pairs with WRITE_ONCE in __xe_exec_queue_init */
struct xe_lrc *lrc = READ_ONCE(q->lrc[0]);
/*
* NOP existing WQ commands that may contain stale GGTT
* addresses. These will be replayed upon unpause. The hardware
* seems to get confused if the WQ head/tail pointers are
* adjusted.
*/
if (lrc)
lrc_parallel_clear(lrc);
}
job = xe_sched_first_pending_job(sched);
if (job) {
job->restore_replay = true;
/*
* Adjust software tail so jobs submitted overwrite previous
* position in ring buffer with new GGTT addresses.
*/
for (i = 0; i < q->width; ++i)
q->lrc[i]->ring.tail = job->ptrs[i].head;
}
}
/**
* xe_guc_submit_pause - Stop further runs of submission tasks on given GuC.
* @guc: the &xe_guc struct instance whose scheduler is to be disabled
*/
void xe_guc_submit_pause(struct xe_guc *guc)
{
struct xe_exec_queue *q;
unsigned long index;
mutex_lock(&guc->submission_state.lock);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q)
xe_sched_submission_stop(&q->guc->sched);
mutex_unlock(&guc->submission_state.lock);
}
/**
* xe_guc_submit_pause_vf - Stop further runs of submission tasks for VF.
* @guc: the &xe_guc struct instance whose scheduler is to be disabled
*/
void xe_guc_submit_pause_vf(struct xe_guc *guc)
{
struct xe_exec_queue *q;
unsigned long index;
xe_gt_assert(guc_to_gt(guc), IS_SRIOV_VF(guc_to_xe(guc)));
xe_gt_assert(guc_to_gt(guc), vf_recovery(guc));
mutex_lock(&guc->submission_state.lock);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q) {
/* Prevent redundant attempts to stop parallel queues */
if (q->guc->id != index)
continue;
guc_exec_queue_pause(guc, q);
}
mutex_unlock(&guc->submission_state.lock);
}
static void guc_exec_queue_start(struct xe_exec_queue *q)
{
struct xe_gpu_scheduler *sched = &q->guc->sched;
if (!exec_queue_killed_or_banned_or_wedged(q)) {
struct xe_sched_job *job = xe_sched_first_pending_job(sched);
int i;
trace_xe_exec_queue_resubmit(q);
if (job) {
for (i = 0; i < q->width; ++i) {
/*
* The GuC context is unregistered at this point
* time, adjusting software ring tail ensures
* jobs are rewritten in original placement,
* adjusting LRC tail ensures the newly loaded
* GuC / contexts only view the LRC tail
* increasing as jobs are written out.
*/
q->lrc[i]->ring.tail = job->ptrs[i].head;
xe_lrc_set_ring_tail(q->lrc[i],
xe_lrc_ring_head(q->lrc[i]));
}
}
xe_sched_resubmit_jobs(sched);
}
xe_sched_submission_start(sched);
xe_sched_submission_resume_tdr(sched);
}
int xe_guc_submit_start(struct xe_guc *guc)
{
struct xe_exec_queue *q;
unsigned long index;
xe_gt_assert(guc_to_gt(guc), xe_guc_read_stopped(guc) == 1);
mutex_lock(&guc->submission_state.lock);
atomic_dec(&guc->submission_state.stopped);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q) {
/* Prevent redundant attempts to start parallel queues */
if (q->guc->id != index)
continue;
guc_exec_queue_start(q);
}
mutex_unlock(&guc->submission_state.lock);
wake_up_all(&guc->ct.wq);
return 0;
}
static void guc_exec_queue_unpause_prepare(struct xe_guc *guc,
struct xe_exec_queue *q)
{
struct xe_gpu_scheduler *sched = &q->guc->sched;
struct xe_sched_job *job = NULL;
struct drm_sched_job *s_job;
bool restore_replay = false;
drm_sched_for_each_pending_job(s_job, &sched->base, NULL) {
job = to_xe_sched_job(s_job);
restore_replay |= job->restore_replay;
if (restore_replay) {
xe_gt_dbg(guc_to_gt(guc), "Replay JOB - guc_id=%d, seqno=%d",
q->guc->id, xe_sched_job_seqno(job));
q->ring_ops->emit_job(job);
job->restore_replay = true;
}
}
if (job)
job->last_replay = true;
}
/**
* xe_guc_submit_unpause_prepare_vf - Prepare unpause submission tasks for VF.
* @guc: the &xe_guc struct instance whose scheduler is to be prepared for unpause
*/
void xe_guc_submit_unpause_prepare_vf(struct xe_guc *guc)
{
struct xe_exec_queue *q;
unsigned long index;
xe_gt_assert(guc_to_gt(guc), IS_SRIOV_VF(guc_to_xe(guc)));
xe_gt_assert(guc_to_gt(guc), vf_recovery(guc));
mutex_lock(&guc->submission_state.lock);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q) {
/* Prevent redundant attempts to stop parallel queues */
if (q->guc->id != index)
continue;
guc_exec_queue_unpause_prepare(guc, q);
}
mutex_unlock(&guc->submission_state.lock);
}
static void guc_exec_queue_replay_pending_state_change(struct xe_exec_queue *q)
{
struct xe_gpu_scheduler *sched = &q->guc->sched;
struct xe_sched_msg *msg;
if (q->guc->needs_cleanup) {
msg = q->guc->static_msgs + STATIC_MSG_CLEANUP;
guc_exec_queue_add_msg(q, msg, CLEANUP);
q->guc->needs_cleanup = false;
}
if (q->guc->needs_suspend) {
msg = q->guc->static_msgs + STATIC_MSG_SUSPEND;
xe_sched_msg_lock(sched);
guc_exec_queue_try_add_msg_head(q, msg, SUSPEND);
xe_sched_msg_unlock(sched);
q->guc->needs_suspend = false;
}
/*
* The resume must be in the message queue before the suspend as it is
* not possible for a resume to be issued if a suspend pending is, but
* the inverse is possible.
*/
if (q->guc->needs_resume) {
msg = q->guc->static_msgs + STATIC_MSG_RESUME;
xe_sched_msg_lock(sched);
guc_exec_queue_try_add_msg_head(q, msg, RESUME);
xe_sched_msg_unlock(sched);
q->guc->needs_resume = false;
}
}
static void guc_exec_queue_unpause(struct xe_guc *guc, struct xe_exec_queue *q)
{
struct xe_gpu_scheduler *sched = &q->guc->sched;
bool needs_tdr = exec_queue_killed_or_banned_or_wedged(q);
lockdep_assert_held(&guc->submission_state.lock);
xe_sched_resubmit_jobs(sched);
guc_exec_queue_replay_pending_state_change(q);
xe_sched_submission_start(sched);
if (needs_tdr)
xe_guc_exec_queue_trigger_cleanup(q);
xe_sched_submission_resume_tdr(sched);
}
/**
* xe_guc_submit_unpause - Allow further runs of submission tasks on given GuC.
* @guc: the &xe_guc struct instance whose scheduler is to be enabled
*/
void xe_guc_submit_unpause(struct xe_guc *guc)
{
struct xe_exec_queue *q;
unsigned long index;
mutex_lock(&guc->submission_state.lock);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q)
xe_sched_submission_start(&q->guc->sched);
mutex_unlock(&guc->submission_state.lock);
}
/**
* xe_guc_submit_unpause_vf - Allow further runs of submission tasks for VF.
* @guc: the &xe_guc struct instance whose scheduler is to be enabled
*/
void xe_guc_submit_unpause_vf(struct xe_guc *guc)
{
struct xe_exec_queue *q;
unsigned long index;
xe_gt_assert(guc_to_gt(guc), IS_SRIOV_VF(guc_to_xe(guc)));
mutex_lock(&guc->submission_state.lock);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q) {
/*
* Prevent redundant attempts to stop parallel queues, or queues
* created after resfix done.
*/
if (q->guc->id != index ||
!drm_sched_is_stopped(&q->guc->sched.base))
continue;
guc_exec_queue_unpause(guc, q);
}
mutex_unlock(&guc->submission_state.lock);
}
/**
* xe_guc_submit_pause_abort - Abort all paused submission task on given GuC.
* @guc: the &xe_guc struct instance whose scheduler is to be aborted
*/
void xe_guc_submit_pause_abort(struct xe_guc *guc)
{
struct xe_exec_queue *q;
unsigned long index;
mutex_lock(&guc->submission_state.lock);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q) {
struct xe_gpu_scheduler *sched = &q->guc->sched;
/* Prevent redundant attempts to stop parallel queues */
if (q->guc->id != index)
continue;
xe_sched_submission_start(sched);
guc_exec_queue_kill(q);
}
mutex_unlock(&guc->submission_state.lock);
}
static struct xe_exec_queue *
g2h_exec_queue_lookup(struct xe_guc *guc, u32 guc_id)
{
struct xe_gt *gt = guc_to_gt(guc);
struct xe_exec_queue *q;
if (unlikely(guc_id >= GUC_ID_MAX)) {
xe_gt_err(gt, "Invalid guc_id %u\n", guc_id);
return NULL;
}
q = xa_load(&guc->submission_state.exec_queue_lookup, guc_id);
if (unlikely(!q)) {
xe_gt_err(gt, "No exec queue found for guc_id %u\n", guc_id);
return NULL;
}
xe_gt_assert(guc_to_gt(guc), guc_id >= q->guc->id);
xe_gt_assert(guc_to_gt(guc), guc_id < (q->guc->id + q->width));
return q;
}
static void deregister_exec_queue(struct xe_guc *guc, struct xe_exec_queue *q)
{
u32 action[] = {
XE_GUC_ACTION_DEREGISTER_CONTEXT,
q->guc->id,
};
xe_gt_assert(guc_to_gt(guc), exec_queue_destroyed(q));
xe_gt_assert(guc_to_gt(guc), exec_queue_registered(q));
xe_gt_assert(guc_to_gt(guc), !exec_queue_pending_disable(q));
xe_gt_assert(guc_to_gt(guc), !exec_queue_pending_enable(q));
trace_xe_exec_queue_deregister(q);
if (xe_exec_queue_is_multi_queue_secondary(q))
handle_deregister_done(guc, q);
else
xe_guc_ct_send_g2h_handler(&guc->ct, action,
ARRAY_SIZE(action));
}
static void handle_sched_done(struct xe_guc *guc, struct xe_exec_queue *q,
u32 runnable_state)
{
trace_xe_exec_queue_scheduling_done(q);
if (runnable_state == 1) {
xe_gt_assert(guc_to_gt(guc), exec_queue_pending_enable(q));
q->guc->resume_time = ktime_get();
clear_exec_queue_pending_resume(q);
clear_exec_queue_pending_enable(q);
smp_wmb();
wake_up_all(&guc->ct.wq);
} else {
xe_gt_assert(guc_to_gt(guc), runnable_state == 0);
xe_gt_assert(guc_to_gt(guc), exec_queue_pending_disable(q));
if (q->guc->suspend_pending) {
suspend_fence_signal(q);
clear_exec_queue_pending_disable(q);
} else {
if (exec_queue_banned(q)) {
smp_wmb();
wake_up_all(&guc->ct.wq);
}
if (exec_queue_destroyed(q)) {
/*
* Make sure to clear the pending_disable only
* after sampling the destroyed state. We want
* to ensure we don't trigger the unregister too
* early with something intending to only
* disable scheduling. The caller doing the
* destroy must wait for an ongoing
* pending_disable before marking as destroyed.
*/
clear_exec_queue_pending_disable(q);
deregister_exec_queue(guc, q);
} else {
clear_exec_queue_pending_disable(q);
}
}
}
}
static void handle_multi_queue_secondary_sched_done(struct xe_guc *guc,
struct xe_exec_queue *q,
u32 runnable_state)
{
/* Take CT lock here as handle_sched_done() do send a h2g message */
mutex_lock(&guc->ct.lock);
handle_sched_done(guc, q, runnable_state);
mutex_unlock(&guc->ct.lock);
}
int xe_guc_sched_done_handler(struct xe_guc *guc, u32 *msg, u32 len)
{
struct xe_exec_queue *q;
u32 guc_id, runnable_state;
if (unlikely(len < 2))
return -EPROTO;
guc_id = msg[0];
runnable_state = msg[1];
q = g2h_exec_queue_lookup(guc, guc_id);
if (unlikely(!q))
return -EPROTO;
if (unlikely(!exec_queue_pending_enable(q) &&
!exec_queue_pending_disable(q))) {
xe_gt_err(guc_to_gt(guc),
"SCHED_DONE: Unexpected engine state 0x%04x, guc_id=%d, runnable_state=%u",
atomic_read(&q->guc->state), q->guc->id,
runnable_state);
return -EPROTO;
}
handle_sched_done(guc, q, runnable_state);
return 0;
}
static void handle_deregister_done(struct xe_guc *guc, struct xe_exec_queue *q)
{
trace_xe_exec_queue_deregister_done(q);
clear_exec_queue_registered(q);
__guc_exec_queue_destroy(guc, q);
}
int xe_guc_deregister_done_handler(struct xe_guc *guc, u32 *msg, u32 len)
{
struct xe_exec_queue *q;
u32 guc_id;
if (unlikely(len < 1))
return -EPROTO;
guc_id = msg[0];
q = g2h_exec_queue_lookup(guc, guc_id);
if (unlikely(!q))
return -EPROTO;
if (!exec_queue_destroyed(q) || exec_queue_pending_disable(q) ||
exec_queue_pending_enable(q) || exec_queue_enabled(q)) {
xe_gt_err(guc_to_gt(guc),
"DEREGISTER_DONE: Unexpected engine state 0x%04x, guc_id=%d",
atomic_read(&q->guc->state), q->guc->id);
return -EPROTO;
}
handle_deregister_done(guc, q);
return 0;
}
int xe_guc_exec_queue_reset_handler(struct xe_guc *guc, u32 *msg, u32 len)
{
struct xe_gt *gt = guc_to_gt(guc);
struct xe_exec_queue *q;
u32 guc_id;
if (unlikely(len < 1))
return -EPROTO;
guc_id = msg[0];
q = g2h_exec_queue_lookup(guc, guc_id);
if (unlikely(!q))
return -EPROTO;
xe_gt_info(gt, "Engine reset: engine_class=%s, logical_mask: 0x%x, guc_id=%d, state=0x%0x",
xe_hw_engine_class_to_str(q->class), q->logical_mask, guc_id,
atomic_read(&q->guc->state));
trace_xe_exec_queue_reset(q);
/*
* A banned engine is a NOP at this point (came from
* guc_exec_queue_timedout_job). Otherwise, kick drm scheduler to cancel
* jobs by setting timeout of the job to the minimum value kicking
* guc_exec_queue_timedout_job.
*/
xe_guc_exec_queue_reset_trigger_cleanup(q);
return 0;
}
/*
* xe_guc_error_capture_handler - Handler of GuC captured message
* @guc: The GuC object
* @msg: Point to the message
* @len: The message length
*
* When GuC captured data is ready, GuC will send message
* XE_GUC_ACTION_STATE_CAPTURE_NOTIFICATION to host, this function will be
* called 1st to check status before process the data comes with the message.
*
* Returns: error code. 0 if success
*/
int xe_guc_error_capture_handler(struct xe_guc *guc, u32 *msg, u32 len)
{
u32 status;
if (unlikely(len != XE_GUC_ACTION_STATE_CAPTURE_NOTIFICATION_DATA_LEN))
return -EPROTO;
status = msg[0] & XE_GUC_STATE_CAPTURE_EVENT_STATUS_MASK;
if (status == XE_GUC_STATE_CAPTURE_EVENT_STATUS_NOSPACE)
xe_gt_warn(guc_to_gt(guc), "G2H-Error capture no space");
xe_guc_capture_process(guc);
return 0;
}
int xe_guc_exec_queue_memory_cat_error_handler(struct xe_guc *guc, u32 *msg,
u32 len)
{
struct xe_gt *gt = guc_to_gt(guc);
struct xe_exec_queue *q;
u32 guc_id;
u32 type = XE_GUC_CAT_ERR_TYPE_INVALID;
if (unlikely(!len || len > 2))
return -EPROTO;
guc_id = msg[0];
if (len == 2)
type = msg[1];
if (guc_id == GUC_ID_UNKNOWN) {
/*
* GuC uses GUC_ID_UNKNOWN if it can not map the CAT fault to any PF/VF
* context. In such case only PF will be notified about that fault.
*/
xe_gt_err_ratelimited(gt, "Memory CAT error reported by GuC!\n");
return 0;
}
q = g2h_exec_queue_lookup(guc, guc_id);
if (unlikely(!q))
return -EPROTO;
/*
* The type is HW-defined and changes based on platform, so we don't
* decode it in the kernel and only check if it is valid.
* See bspec 54047 and 72187 for details.
*/
if (type != XE_GUC_CAT_ERR_TYPE_INVALID)
xe_gt_info(gt,
"Engine memory CAT error [%u]: class=%s, logical_mask: 0x%x, guc_id=%d",
type, xe_hw_engine_class_to_str(q->class), q->logical_mask, guc_id);
else
xe_gt_info(gt,
"Engine memory CAT error: class=%s, logical_mask: 0x%x, guc_id=%d",
xe_hw_engine_class_to_str(q->class), q->logical_mask, guc_id);
trace_xe_exec_queue_memory_cat_error(q);
/* Treat the same as engine reset */
xe_guc_exec_queue_reset_trigger_cleanup(q);
return 0;
}
int xe_guc_exec_queue_reset_failure_handler(struct xe_guc *guc, u32 *msg, u32 len)
{
struct xe_gt *gt = guc_to_gt(guc);
u8 guc_class, instance;
u32 reason;
if (unlikely(len != 3))
return -EPROTO;
guc_class = msg[0];
instance = msg[1];
reason = msg[2];
/* Unexpected failure of a hardware feature, log an actual error */
xe_gt_err(gt, "GuC engine reset request failed on %d:%d because 0x%08X",
guc_class, instance, reason);
xe_gt_reset_async(gt);
return 0;
}
int xe_guc_exec_queue_cgp_context_error_handler(struct xe_guc *guc, u32 *msg,
u32 len)
{
struct xe_gt *gt = guc_to_gt(guc);
struct xe_device *xe = guc_to_xe(guc);
struct xe_exec_queue *q;
u32 guc_id = msg[2];
if (unlikely(len != XE_GUC_EXEC_QUEUE_CGP_CONTEXT_ERROR_LEN)) {
drm_err(&xe->drm, "Invalid length %u", len);
return -EPROTO;
}
q = g2h_exec_queue_lookup(guc, guc_id);
if (unlikely(!q))
return -EPROTO;
xe_gt_dbg(gt,
"CGP context error: [%s] err=0x%x, q0_id=0x%x LRCA=0x%x guc_id=0x%x",
msg[0] & 1 ? "uc" : "kmd", msg[1], msg[2], msg[3], msg[4]);
trace_xe_exec_queue_cgp_context_error(q);
/* Treat the same as engine reset */
xe_guc_exec_queue_reset_trigger_cleanup(q);
return 0;
}
/**
* xe_guc_exec_queue_cgp_sync_done_handler - CGP synchronization done handler
* @guc: guc
* @msg: message indicating CGP sync done
* @len: length of message
*
* Set multi queue group's sync_pending flag to false and wakeup anyone waiting
* for CGP synchronization to complete.
*
* Return: 0 on success, -EPROTO for malformed messages.
*/
int xe_guc_exec_queue_cgp_sync_done_handler(struct xe_guc *guc, u32 *msg, u32 len)
{
struct xe_device *xe = guc_to_xe(guc);
struct xe_exec_queue *q;
u32 guc_id = msg[0];
if (unlikely(len < 1)) {
drm_err(&xe->drm, "Invalid CGP_SYNC_DONE length %u", len);
return -EPROTO;
}
q = g2h_exec_queue_lookup(guc, guc_id);
if (unlikely(!q))
return -EPROTO;
if (!xe_exec_queue_is_multi_queue_primary(q)) {
drm_err(&xe->drm, "Unexpected CGP_SYNC_DONE response");
return -EPROTO;
}
/* Wakeup the serialized cgp update wait */
WRITE_ONCE(q->multi_queue.group->sync_pending, false);
xe_guc_ct_wake_waiters(&guc->ct);
return 0;
}
static void
guc_exec_queue_wq_snapshot_capture(struct xe_exec_queue *q,
struct xe_guc_submit_exec_queue_snapshot *snapshot)
{
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_device *xe = guc_to_xe(guc);
struct iosys_map map = xe_lrc_parallel_map(q->lrc[0]);
int i;
snapshot->guc.wqi_head = q->guc->wqi_head;
snapshot->guc.wqi_tail = q->guc->wqi_tail;
snapshot->parallel.wq_desc.head = parallel_read(xe, map, wq_desc.head);
snapshot->parallel.wq_desc.tail = parallel_read(xe, map, wq_desc.tail);
snapshot->parallel.wq_desc.status = parallel_read(xe, map,
wq_desc.wq_status);
if (snapshot->parallel.wq_desc.head !=
snapshot->parallel.wq_desc.tail) {
for (i = snapshot->parallel.wq_desc.head;
i != snapshot->parallel.wq_desc.tail;
i = (i + sizeof(u32)) % WQ_SIZE)
snapshot->parallel.wq[i / sizeof(u32)] =
parallel_read(xe, map, wq[i / sizeof(u32)]);
}
}
static void
guc_exec_queue_wq_snapshot_print(struct xe_guc_submit_exec_queue_snapshot *snapshot,
struct drm_printer *p)
{
int i;
drm_printf(p, "\tWQ head: %u (internal), %d (memory)\n",
snapshot->guc.wqi_head, snapshot->parallel.wq_desc.head);
drm_printf(p, "\tWQ tail: %u (internal), %d (memory)\n",
snapshot->guc.wqi_tail, snapshot->parallel.wq_desc.tail);
drm_printf(p, "\tWQ status: %u\n", snapshot->parallel.wq_desc.status);
if (snapshot->parallel.wq_desc.head !=
snapshot->parallel.wq_desc.tail) {
for (i = snapshot->parallel.wq_desc.head;
i != snapshot->parallel.wq_desc.tail;
i = (i + sizeof(u32)) % WQ_SIZE)
drm_printf(p, "\tWQ[%zu]: 0x%08x\n", i / sizeof(u32),
snapshot->parallel.wq[i / sizeof(u32)]);
}
}
/**
* xe_guc_exec_queue_snapshot_capture - Take a quick snapshot of the GuC Engine.
* @q: faulty exec queue
*
* This can be printed out in a later stage like during dev_coredump
* analysis.
*
* Returns: a GuC Submit Engine snapshot object that must be freed by the
* caller, using `xe_guc_exec_queue_snapshot_free`.
*/
struct xe_guc_submit_exec_queue_snapshot *
xe_guc_exec_queue_snapshot_capture(struct xe_exec_queue *q)
{
struct xe_gpu_scheduler *sched = &q->guc->sched;
struct xe_guc_submit_exec_queue_snapshot *snapshot;
int i;
snapshot = kzalloc_obj(*snapshot, GFP_ATOMIC);
if (!snapshot)
return NULL;
snapshot->guc.id = q->guc->id;
memcpy(&snapshot->name, &q->name, sizeof(snapshot->name));
snapshot->class = q->class;
snapshot->logical_mask = q->logical_mask;
snapshot->width = q->width;
snapshot->refcount = kref_read(&q->refcount);
snapshot->sched_timeout = sched->base.timeout;
snapshot->sched_props.timeslice_us = q->sched_props.timeslice_us;
snapshot->sched_props.preempt_timeout_us =
q->sched_props.preempt_timeout_us;
snapshot->lrc = kmalloc_objs(struct xe_lrc_snapshot *, q->width,
GFP_ATOMIC);
if (snapshot->lrc) {
for (i = 0; i < q->width; ++i) {
struct xe_lrc *lrc = q->lrc[i];
snapshot->lrc[i] = xe_lrc_snapshot_capture(lrc);
}
}
snapshot->schedule_state = atomic_read(&q->guc->state);
snapshot->exec_queue_flags = q->flags;
snapshot->parallel_execution = xe_exec_queue_is_parallel(q);
if (snapshot->parallel_execution)
guc_exec_queue_wq_snapshot_capture(q, snapshot);
if (xe_exec_queue_is_multi_queue(q)) {
snapshot->multi_queue.valid = true;
snapshot->multi_queue.primary = xe_exec_queue_multi_queue_primary(q)->guc->id;
snapshot->multi_queue.pos = q->multi_queue.pos;
}
return snapshot;
}
/**
* xe_guc_exec_queue_snapshot_capture_delayed - Take delayed part of snapshot of the GuC Engine.
* @snapshot: Previously captured snapshot of job.
*
* This captures some data that requires taking some locks, so it cannot be done in signaling path.
*/
void
xe_guc_exec_queue_snapshot_capture_delayed(struct xe_guc_submit_exec_queue_snapshot *snapshot)
{
int i;
if (!snapshot || !snapshot->lrc)
return;
for (i = 0; i < snapshot->width; ++i)
xe_lrc_snapshot_capture_delayed(snapshot->lrc[i]);
}
/**
* xe_guc_exec_queue_snapshot_print - Print out a given GuC Engine snapshot.
* @snapshot: GuC Submit Engine snapshot object.
* @p: drm_printer where it will be printed out.
*
* This function prints out a given GuC Submit Engine snapshot object.
*/
void
xe_guc_exec_queue_snapshot_print(struct xe_guc_submit_exec_queue_snapshot *snapshot,
struct drm_printer *p)
{
int i;
if (!snapshot)
return;
drm_printf(p, "GuC ID: %d\n", snapshot->guc.id);
drm_printf(p, "\tName: %s\n", snapshot->name);
drm_printf(p, "\tClass: %d\n", snapshot->class);
drm_printf(p, "\tLogical mask: 0x%x\n", snapshot->logical_mask);
drm_printf(p, "\tWidth: %d\n", snapshot->width);
drm_printf(p, "\tRef: %d\n", snapshot->refcount);
drm_printf(p, "\tTimeout: %ld (ms)\n", snapshot->sched_timeout);
drm_printf(p, "\tTimeslice: %u (us)\n",
snapshot->sched_props.timeslice_us);
drm_printf(p, "\tPreempt timeout: %u (us)\n",
snapshot->sched_props.preempt_timeout_us);
for (i = 0; snapshot->lrc && i < snapshot->width; ++i)
xe_lrc_snapshot_print(snapshot->lrc[i], p);
drm_printf(p, "\tSchedule State: 0x%x\n", snapshot->schedule_state);
drm_printf(p, "\tFlags: 0x%lx\n", snapshot->exec_queue_flags);
if (snapshot->parallel_execution)
guc_exec_queue_wq_snapshot_print(snapshot, p);
if (snapshot->multi_queue.valid) {
drm_printf(p, "\tMulti queue primary GuC ID: %d\n", snapshot->multi_queue.primary);
drm_printf(p, "\tMulti queue position: %d\n", snapshot->multi_queue.pos);
}
}
/**
* xe_guc_exec_queue_snapshot_free - Free all allocated objects for a given
* snapshot.
* @snapshot: GuC Submit Engine snapshot object.
*
* This function free all the memory that needed to be allocated at capture
* time.
*/
void xe_guc_exec_queue_snapshot_free(struct xe_guc_submit_exec_queue_snapshot *snapshot)
{
int i;
if (!snapshot)
return;
if (snapshot->lrc) {
for (i = 0; i < snapshot->width; i++)
xe_lrc_snapshot_free(snapshot->lrc[i]);
kfree(snapshot->lrc);
}
kfree(snapshot);
}
static void guc_exec_queue_print(struct xe_exec_queue *q, struct drm_printer *p)
{
struct xe_guc_submit_exec_queue_snapshot *snapshot;
snapshot = xe_guc_exec_queue_snapshot_capture(q);
xe_guc_exec_queue_snapshot_print(snapshot, p);
xe_guc_exec_queue_snapshot_free(snapshot);
}
/**
* xe_guc_register_vf_exec_queue - Register exec queue for a given context type.
* @q: Execution queue
* @ctx_type: Type of the context
*
* This function registers the execution queue with the guc. Special context
* types like GUC_CONTEXT_COMPRESSION_SAVE and GUC_CONTEXT_COMPRESSION_RESTORE
* are only applicable for IGPU and in the VF.
* Submits the execution queue to GUC after registering it.
*
* Returns - None.
*/
void xe_guc_register_vf_exec_queue(struct xe_exec_queue *q, int ctx_type)
{
struct xe_guc *guc = exec_queue_to_guc(q);
struct xe_device *xe = guc_to_xe(guc);
struct xe_gt *gt = guc_to_gt(guc);
xe_gt_assert(gt, IS_SRIOV_VF(xe));
xe_gt_assert(gt, !IS_DGFX(xe));
xe_gt_assert(gt, ctx_type == GUC_CONTEXT_COMPRESSION_SAVE ||
ctx_type == GUC_CONTEXT_COMPRESSION_RESTORE);
xe_gt_assert(gt, GUC_SUBMIT_VER(guc) >= MAKE_GUC_VER(1, 23, 0));
register_exec_queue(q, ctx_type);
enable_scheduling(q);
}
/**
* xe_guc_submit_print - GuC Submit Print.
* @guc: GuC.
* @p: drm_printer where it will be printed out.
*
* This function capture and prints snapshots of **all** GuC Engines.
*/
void xe_guc_submit_print(struct xe_guc *guc, struct drm_printer *p)
{
struct xe_exec_queue *q;
unsigned long index;
if (!xe_device_uc_enabled(guc_to_xe(guc)))
return;
mutex_lock(&guc->submission_state.lock);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q)
guc_exec_queue_print(q, p);
mutex_unlock(&guc->submission_state.lock);
}
/**
* xe_guc_has_registered_mlrc_queues - check whether there are any MLRC queues
* registered with the GuC
* @guc: GuC.
*
* Return: true if any MLRC queue is registered with the GuC, false otherwise.
*/
bool xe_guc_has_registered_mlrc_queues(struct xe_guc *guc)
{
struct xe_exec_queue *q;
unsigned long index;
guard(mutex)(&guc->submission_state.lock);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q)
if (q->width > 1)
return true;
return false;
}
/**
* xe_guc_contexts_hwsp_rebase - Re-compute GGTT references within all
* exec queues registered to given GuC.
* @guc: the &xe_guc struct instance
* @scratch: scratch buffer to be used as temporary storage
*
* Returns: zero on success, negative error code on failure.
*/
int xe_guc_contexts_hwsp_rebase(struct xe_guc *guc, void *scratch)
{
struct xe_exec_queue *q;
unsigned long index;
int err = 0;
mutex_lock(&guc->submission_state.lock);
xa_for_each(&guc->submission_state.exec_queue_lookup, index, q) {
/* Prevent redundant attempts to stop parallel queues */
if (q->guc->id != index)
continue;
err = xe_exec_queue_contexts_hwsp_rebase(q, scratch);
if (err)
break;
}
mutex_unlock(&guc->submission_state.lock);
return err;
}
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