drivers/gpu/drm/xe/xe_devcoredump.c - linux - Git at Google

 // SPDX-License-Identifier: MIT
 /*
  * Copyright © 2023 Intel Corporation
  */

 #include "xe_devcoredump.h"
 #include "xe_devcoredump_types.h"

 #include <linux/ascii85.h>
 #include <linux/devcoredump.h>
 #include <generated/utsrelease.h>

 #include <drm/drm_managed.h>

 #include "xe_device.h"
 #include "xe_exec_queue.h"
 #include "xe_force_wake.h"
 #include "xe_gt.h"
 #include "xe_gt_printk.h"
 #include "xe_guc_capture.h"
 #include "xe_guc_ct.h"
 #include "xe_guc_log.h"
 #include "xe_guc_submit.h"
 #include "xe_hw_engine.h"
 #include "xe_module.h"
 #include "xe_pm.h"
 #include "xe_sched_job.h"
 #include "xe_vm.h"

 /**
  * DOC: Xe device coredump
  *
  * Xe uses dev_coredump infrastructure for exposing the crash errors in a
  * standardized way. Once a crash occurs, devcoredump exposes a temporary
  * node under ``/sys/class/devcoredump/devcd<m>/``. The same node is also
  * accessible in ``/sys/class/drm/card<n>/device/devcoredump/``. The
  * ``failing_device`` symlink points to the device that crashed and created the
  * coredump.
  *
  * The following characteristics are observed by xe when creating a device
  * coredump:
  *
  * **Snapshot at hang**:
  *   The 'data' file contains a snapshot of the HW and driver states at the time
  *   the hang happened. Due to the driver recovering from resets/crashes, it may
  *   not correspond to the state of the system when the file is read by
  *   userspace.
  *
  * **Coredump release**:
  *   After a coredump is generated, it stays in kernel memory until released by
  *   userspace by writing anything to it, or after an internal timer expires. The
  *   exact timeout may vary and should not be relied upon. Example to release
  *   a coredump:
  *
  *   .. code-block:: shell
  *
  *	$ > /sys/class/drm/card0/device/devcoredump/data
  *
  * **First failure only**:
  *   In general, the first hang is the most critical one since the following
  *   hangs can be a consequence of the initial hang. For this reason a snapshot
  *   is taken only for the first failure. Until the devcoredump is released by
  *   userspace or kernel, all subsequent hangs do not override the snapshot nor
  *   create new ones. Devcoredump has a delayed work queue that will eventually
  *   delete the file node and free all the dump information.
  */

 #ifdef CONFIG_DEV_COREDUMP

 /* 1 hour timeout */
 #define XE_COREDUMP_TIMEOUT_JIFFIES (60 * 60 * HZ)

 static struct xe_device *coredump_to_xe(const struct xe_devcoredump *coredump)
 {
 	return container_of(coredump, struct xe_device, devcoredump);
 }

 static struct xe_guc *exec_queue_to_guc(struct xe_exec_queue *q)
 {
 	return &q->gt->uc.guc;
 }

 static ssize_t __xe_devcoredump_read(char *buffer, size_t count,
 				     struct xe_devcoredump *coredump)
 {
 	struct xe_device *xe;
 	struct xe_devcoredump_snapshot *ss;
 	struct drm_printer p;
 	struct drm_print_iterator iter;
 	struct timespec64 ts;
 	int i;

 	xe = coredump_to_xe(coredump);
 	ss = &coredump->snapshot;

 	iter.data = buffer;
 	iter.start = 0;
 	iter.remain = count;

 	p = drm_coredump_printer(&iter);

 	drm_puts(&p, "**** Xe Device Coredump ****\n");
 	drm_printf(&p, "Reason: %s\n", ss->reason);
 	drm_puts(&p, "kernel: " UTS_RELEASE "\n");
 	drm_puts(&p, "module: " KBUILD_MODNAME "\n");

 	ts = ktime_to_timespec64(ss->snapshot_time);
 	drm_printf(&p, "Snapshot time: %lld.%09ld\n", ts.tv_sec, ts.tv_nsec);
 	ts = ktime_to_timespec64(ss->boot_time);
 	drm_printf(&p, "Uptime: %lld.%09ld\n", ts.tv_sec, ts.tv_nsec);
 	drm_printf(&p, "Process: %s [%d]\n", ss->process_name, ss->pid);
 	xe_device_snapshot_print(xe, &p);

 	drm_printf(&p, "\n**** GT #%d ****\n", ss->gt->info.id);
 	drm_printf(&p, "\tTile: %d\n", ss->gt->tile->id);

 	drm_puts(&p, "\n**** GuC Log ****\n");
 	xe_guc_log_snapshot_print(ss->guc.log, &p);
 	drm_puts(&p, "\n**** GuC CT ****\n");
 	xe_guc_ct_snapshot_print(ss->guc.ct, &p);

 	drm_puts(&p, "\n**** Contexts ****\n");
 	xe_guc_exec_queue_snapshot_print(ss->ge, &p);

 	drm_puts(&p, "\n**** Job ****\n");
 	xe_sched_job_snapshot_print(ss->job, &p);

 	drm_puts(&p, "\n**** HW Engines ****\n");
 	for (i = 0; i < XE_NUM_HW_ENGINES; i++)
 		if (ss->hwe[i])
 			xe_engine_snapshot_print(ss->hwe[i], &p);

 	drm_puts(&p, "\n**** VM state ****\n");
 	xe_vm_snapshot_print(ss->vm, &p);

 	return count - iter.remain;
 }

 static void xe_devcoredump_snapshot_free(struct xe_devcoredump_snapshot *ss)
 {
 	int i;

 	kfree(ss->reason);
 	ss->reason = NULL;

 	xe_guc_log_snapshot_free(ss->guc.log);
 	ss->guc.log = NULL;

 	xe_guc_ct_snapshot_free(ss->guc.ct);
 	ss->guc.ct = NULL;

 	xe_guc_capture_put_matched_nodes(&ss->gt->uc.guc);
 	ss->matched_node = NULL;

 	xe_guc_exec_queue_snapshot_free(ss->ge);
 	ss->ge = NULL;

 	xe_sched_job_snapshot_free(ss->job);
 	ss->job = NULL;

 	for (i = 0; i < XE_NUM_HW_ENGINES; i++)
 		if (ss->hwe[i]) {
 			xe_hw_engine_snapshot_free(ss->hwe[i]);
 			ss->hwe[i] = NULL;
 		}

 	xe_vm_snapshot_free(ss->vm);
 	ss->vm = NULL;
 }

 static ssize_t xe_devcoredump_read(char *buffer, loff_t offset,
 				   size_t count, void *data, size_t datalen)
 {
 	struct xe_devcoredump *coredump = data;
 	struct xe_devcoredump_snapshot *ss;
 	ssize_t byte_copied;

 	if (!coredump)
 		return -ENODEV;

 	ss = &coredump->snapshot;

 	/* Ensure delayed work is captured before continuing */
 	flush_work(&ss->work);

 	mutex_lock(&coredump->lock);

 	if (!ss->read.buffer) {
 		mutex_unlock(&coredump->lock);
 		return -ENODEV;
 	}

 	if (offset >= ss->read.size) {
 		mutex_unlock(&coredump->lock);
 		return 0;
 	}

 	byte_copied = count < ss->read.size - offset ? count :
 		ss->read.size - offset;
 	memcpy(buffer, ss->read.buffer + offset, byte_copied);

 	mutex_unlock(&coredump->lock);

 	return byte_copied;
 }

 static void xe_devcoredump_free(void *data)
 {
 	struct xe_devcoredump *coredump = data;

 	/* Our device is gone. Nothing to do... */
 	if (!data || !coredump_to_xe(coredump))
 		return;

 	cancel_work_sync(&coredump->snapshot.work);

 	mutex_lock(&coredump->lock);

 	xe_devcoredump_snapshot_free(&coredump->snapshot);
 	kvfree(coredump->snapshot.read.buffer);

 	/* To prevent stale data on next snapshot, clear everything */
 	memset(&coredump->snapshot, 0, sizeof(coredump->snapshot));
 	coredump->captured = false;
 	drm_info(&coredump_to_xe(coredump)->drm,
 		 "Xe device coredump has been deleted.\n");

 	mutex_unlock(&coredump->lock);
 }

 static void xe_devcoredump_deferred_snap_work(struct work_struct *work)
 {
 	struct xe_devcoredump_snapshot *ss = container_of(work, typeof(*ss), work);
 	struct xe_devcoredump *coredump = container_of(ss, typeof(*coredump), snapshot);
 	struct xe_device *xe = coredump_to_xe(coredump);
 	unsigned int fw_ref;

 	/*
 	 * NB: Despite passing a GFP_ flags parameter here, more allocations are done
 	 * internally using GFP_KERNEL explicitly. Hence this call must be in the worker
 	 * thread and not in the initial capture call.
 	 */
 	dev_coredumpm_timeout(gt_to_xe(ss->gt)->drm.dev, THIS_MODULE, coredump, 0, GFP_KERNEL,
 			      xe_devcoredump_read, xe_devcoredump_free,
 			      XE_COREDUMP_TIMEOUT_JIFFIES);

 	xe_pm_runtime_get(xe);

 	/* keep going if fw fails as we still want to save the memory and SW data */
 	fw_ref = xe_force_wake_get(gt_to_fw(ss->gt), XE_FORCEWAKE_ALL);
 	if (!xe_force_wake_ref_has_domain(fw_ref, XE_FORCEWAKE_ALL))
 		xe_gt_info(ss->gt, "failed to get forcewake for coredump capture\n");
 	xe_vm_snapshot_capture_delayed(ss->vm);
 	xe_guc_exec_queue_snapshot_capture_delayed(ss->ge);
 	xe_force_wake_put(gt_to_fw(ss->gt), fw_ref);

 	xe_pm_runtime_put(xe);

 	/* Calculate devcoredump size */
 	ss->read.size = __xe_devcoredump_read(NULL, INT_MAX, coredump);

 	ss->read.buffer = kvmalloc(ss->read.size, GFP_USER);
 	if (!ss->read.buffer)
 		return;

 	__xe_devcoredump_read(ss->read.buffer, ss->read.size, coredump);
 	xe_devcoredump_snapshot_free(ss);
 }

 static void devcoredump_snapshot(struct xe_devcoredump *coredump,
 				 struct xe_exec_queue *q,
 				 struct xe_sched_job *job)
 {
 	struct xe_devcoredump_snapshot *ss = &coredump->snapshot;
 	struct xe_guc *guc = exec_queue_to_guc(q);
 	u32 adj_logical_mask = q->logical_mask;
 	u32 width_mask = (0x1 << q->width) - 1;
 	const char *process_name = "no process";

 	unsigned int fw_ref;
 	bool cookie;
 	int i;

 	ss->snapshot_time = ktime_get_real();
 	ss->boot_time = ktime_get_boottime();

 	if (q->vm && q->vm->xef) {
 		process_name = q->vm->xef->process_name;
 		ss->pid = q->vm->xef->pid;
 	}

 	strscpy(ss->process_name, process_name);

 	ss->gt = q->gt;
 	INIT_WORK(&ss->work, xe_devcoredump_deferred_snap_work);

 	cookie = dma_fence_begin_signalling();
 	for (i = 0; q->width > 1 && i < XE_HW_ENGINE_MAX_INSTANCE;) {
 		if (adj_logical_mask & BIT(i)) {
 			adj_logical_mask |= width_mask << i;
 			i += q->width;
 		} else {
 			++i;
 		}
 	}

 	/* keep going if fw fails as we still want to save the memory and SW data */
 	fw_ref = xe_force_wake_get(gt_to_fw(q->gt), XE_FORCEWAKE_ALL);

 	ss->guc.log = xe_guc_log_snapshot_capture(&guc->log, true);
 	ss->guc.ct = xe_guc_ct_snapshot_capture(&guc->ct);
 	ss->ge = xe_guc_exec_queue_snapshot_capture(q);
 	if (job)
 		ss->job = xe_sched_job_snapshot_capture(job);
 	ss->vm = xe_vm_snapshot_capture(q->vm);

 	xe_engine_snapshot_capture_for_queue(q);

 	queue_work(system_unbound_wq, &ss->work);

 	xe_force_wake_put(gt_to_fw(q->gt), fw_ref);
 	dma_fence_end_signalling(cookie);
 }

 /**
  * xe_devcoredump - Take the required snapshots and initialize coredump device.
  * @q: The faulty xe_exec_queue, where the issue was detected.
  * @job: The faulty xe_sched_job, where the issue was detected.
  * @fmt: Printf format + args to describe the reason for the core dump
  *
  * This function should be called at the crash time within the serialized
  * gt_reset. It is skipped if we still have the core dump device available
  * with the information of the 'first' snapshot.
  */
 __printf(3, 4)
 void xe_devcoredump(struct xe_exec_queue *q, struct xe_sched_job *job, const char *fmt, ...)
 {
 	struct xe_device *xe = gt_to_xe(q->gt);
 	struct xe_devcoredump *coredump = &xe->devcoredump;
 	va_list varg;

 	mutex_lock(&coredump->lock);

 	if (coredump->captured) {
 		drm_dbg(&xe->drm, "Multiple hangs are occurring, but only the first snapshot was taken\n");
 		mutex_unlock(&coredump->lock);
 		return;
 	}

 	coredump->captured = true;

 	va_start(varg, fmt);
 	coredump->snapshot.reason = kvasprintf(GFP_ATOMIC, fmt, varg);
 	va_end(varg);

 	devcoredump_snapshot(coredump, q, job);

 	drm_info(&xe->drm, "Xe device coredump has been created\n");
 	drm_info(&xe->drm, "Check your /sys/class/drm/card%d/device/devcoredump/data\n",
 		 xe->drm.primary->index);

 	mutex_unlock(&coredump->lock);
 }

 static void xe_driver_devcoredump_fini(void *arg)
 {
 	struct drm_device *drm = arg;

 	dev_coredump_put(drm->dev);
 }

 int xe_devcoredump_init(struct xe_device *xe)
 {
 	int err;

 	err = drmm_mutex_init(&xe->drm, &xe->devcoredump.lock);
 	if (err)
 		return err;

 	if (IS_ENABLED(CONFIG_LOCKDEP)) {
 		fs_reclaim_acquire(GFP_KERNEL);
 		might_lock(&xe->devcoredump.lock);
 		fs_reclaim_release(GFP_KERNEL);
 	}

 	return devm_add_action_or_reset(xe->drm.dev, xe_driver_devcoredump_fini, &xe->drm);
 }

 #endif

 /**
  * xe_print_blob_ascii85 - print a BLOB to some useful location in ASCII85
  *
  * The output is split into multiple calls to drm_puts() because some print
  * targets, e.g. dmesg, cannot handle arbitrarily long lines. These targets may
  * add newlines, as is the case with dmesg: each drm_puts() call creates a
  * separate line.
  *
  * There is also a scheduler yield call to prevent the 'task has been stuck for
  * 120s' kernel hang check feature from firing when printing to a slow target
  * such as dmesg over a serial port.
  *
  * @p: the printer object to output to
  * @prefix: optional prefix to add to output string
  * @suffix: optional suffix to add at the end. 0 disables it and is
  *          not added to the output, which is useful when using multiple calls
  *          to dump data to @p
  * @blob: the Binary Large OBject to dump out
  * @offset: offset in bytes to skip from the front of the BLOB, must be a multiple of sizeof(u32)
  * @size: the size in bytes of the BLOB, must be a multiple of sizeof(u32)
  */
 void xe_print_blob_ascii85(struct drm_printer *p, const char *prefix, char suffix,
 			   const void *blob, size_t offset, size_t size)
 {
 	const u32 *blob32 = (const u32 *)blob;
 	char buff[ASCII85_BUFSZ], *line_buff;
 	size_t line_pos = 0;

 #define DMESG_MAX_LINE_LEN	800
 	/* Always leave space for the suffix char and the \0 */
 #define MIN_SPACE		(ASCII85_BUFSZ + 2)	/* 85 + "<suffix>\0" */

 	if (size & 3)
 		drm_printf(p, "Size not word aligned: %zu", size);
 	if (offset & 3)
 		drm_printf(p, "Offset not word aligned: %zu", offset);

 	line_buff = kzalloc(DMESG_MAX_LINE_LEN, GFP_KERNEL);
 	if (!line_buff) {
 		drm_printf(p, "Failed to allocate line buffer\n");
 		return;
 	}

 	blob32 += offset / sizeof(*blob32);
 	size /= sizeof(*blob32);

 	if (prefix) {
 		strscpy(line_buff, prefix, DMESG_MAX_LINE_LEN - MIN_SPACE - 2);
 		line_pos = strlen(line_buff);

 		line_buff[line_pos++] = ':';
 		line_buff[line_pos++] = ' ';
 	}

 	while (size--) {
 		u32 val = *(blob32++);

 		strscpy(line_buff + line_pos, ascii85_encode(val, buff),
 			DMESG_MAX_LINE_LEN - line_pos);
 		line_pos += strlen(line_buff + line_pos);

 		if ((line_pos + MIN_SPACE) >= DMESG_MAX_LINE_LEN) {
 			line_buff[line_pos++] = 0;

 			drm_puts(p, line_buff);

 			line_pos = 0;

 			/* Prevent 'stuck thread' time out errors */
 			cond_resched();
 		}
 	}

 	if (suffix)
 		line_buff[line_pos++] = suffix;

 	if (line_pos) {
 		line_buff[line_pos++] = 0;
 		drm_puts(p, line_buff);
 	}

 	kfree(line_buff);

 #undef MIN_SPACE
 #undef DMESG_MAX_LINE_LEN
 }
	// SPDX-License-Identifier: MIT
	/*
	* Copyright © 2023 Intel Corporation
	*/

	#include "xe_devcoredump.h"
	#include "xe_devcoredump_types.h"

	#include <linux/ascii85.h>
	#include <linux/devcoredump.h>
	#include <generated/utsrelease.h>

	#include <drm/drm_managed.h>

	#include "xe_device.h"
	#include "xe_exec_queue.h"
	#include "xe_force_wake.h"
	#include "xe_gt.h"
	#include "xe_gt_printk.h"
	#include "xe_guc_capture.h"
	#include "xe_guc_ct.h"
	#include "xe_guc_log.h"
	#include "xe_guc_submit.h"
	#include "xe_hw_engine.h"
	#include "xe_module.h"
	#include "xe_pm.h"
	#include "xe_sched_job.h"
	#include "xe_vm.h"

	/**
	* DOC: Xe device coredump
	*
	* Xe uses dev_coredump infrastructure for exposing the crash errors in a
	* standardized way. Once a crash occurs, devcoredump exposes a temporary
	* node under ``/sys/class/devcoredump/devcd<m>/``. The same node is also
	* accessible in ``/sys/class/drm/card<n>/device/devcoredump/``. The
	* ``failing_device`` symlink points to the device that crashed and created the
	* coredump.
	*
	* The following characteristics are observed by xe when creating a device
	* coredump:
	*
	* Snapshot at hang:
	* The 'data' file contains a snapshot of the HW and driver states at the time
	* the hang happened. Due to the driver recovering from resets/crashes, it may
	* not correspond to the state of the system when the file is read by
	* userspace.
	*
	* Coredump release:
	* After a coredump is generated, it stays in kernel memory until released by
	* userspace by writing anything to it, or after an internal timer expires. The
	* exact timeout may vary and should not be relied upon. Example to release
	* a coredump:
	*
	* .. code-block:: shell
	*
	* $ > /sys/class/drm/card0/device/devcoredump/data
	*
	* First failure only:
	* In general, the first hang is the most critical one since the following
	* hangs can be a consequence of the initial hang. For this reason a snapshot
	* is taken only for the first failure. Until the devcoredump is released by
	* userspace or kernel, all subsequent hangs do not override the snapshot nor
	* create new ones. Devcoredump has a delayed work queue that will eventually
	* delete the file node and free all the dump information.
	*/

	#ifdef CONFIG_DEV_COREDUMP

	/* 1 hour timeout */
	#define XE_COREDUMP_TIMEOUT_JIFFIES (60 * 60 * HZ)

	static struct xe_device coredump_to_xe(const struct xe_devcoredump coredump)
	{
	return container_of(coredump, struct xe_device, devcoredump);
	}

	static struct xe_guc exec_queue_to_guc(struct xe_exec_queue q)
	{
	return &q->gt->uc.guc;
	}

	static ssize_t __xe_devcoredump_read(char *buffer, size_t count,
	struct xe_devcoredump *coredump)
	{
	struct xe_device *xe;
	struct xe_devcoredump_snapshot *ss;
	struct drm_printer p;
	struct drm_print_iterator iter;
	struct timespec64 ts;
	int i;

	xe = coredump_to_xe(coredump);
	ss = &coredump->snapshot;

	iter.data = buffer;
	iter.start = 0;
	iter.remain = count;

	p = drm_coredump_printer(&iter);

	drm_puts(&p, "** Xe Device Coredump **\n");
	drm_printf(&p, "Reason: %s\n", ss->reason);
	drm_puts(&p, "kernel: " UTS_RELEASE "\n");
	drm_puts(&p, "module: " KBUILD_MODNAME "\n");

	ts = ktime_to_timespec64(ss->snapshot_time);
	drm_printf(&p, "Snapshot time: %lld.%09ld\n", ts.tv_sec, ts.tv_nsec);
	ts = ktime_to_timespec64(ss->boot_time);
	drm_printf(&p, "Uptime: %lld.%09ld\n", ts.tv_sec, ts.tv_nsec);
	drm_printf(&p, "Process: %s [%d]\n", ss->process_name, ss->pid);
	xe_device_snapshot_print(xe, &p);

	drm_printf(&p, "\n** GT #%d **\n", ss->gt->info.id);
	drm_printf(&p, "\tTile: %d\n", ss->gt->tile->id);

	drm_puts(&p, "\n** GuC Log **\n");
	xe_guc_log_snapshot_print(ss->guc.log, &p);
	drm_puts(&p, "\n** GuC CT **\n");
	xe_guc_ct_snapshot_print(ss->guc.ct, &p);

	drm_puts(&p, "\n** Contexts **\n");
	xe_guc_exec_queue_snapshot_print(ss->ge, &p);

	drm_puts(&p, "\n** Job **\n");
	xe_sched_job_snapshot_print(ss->job, &p);

	drm_puts(&p, "\n** HW Engines **\n");
	for (i = 0; i < XE_NUM_HW_ENGINES; i++)
	if (ss->hwe[i])
	xe_engine_snapshot_print(ss->hwe[i], &p);

	drm_puts(&p, "\n** VM state **\n");
	xe_vm_snapshot_print(ss->vm, &p);

	return count - iter.remain;
	}

	static void xe_devcoredump_snapshot_free(struct xe_devcoredump_snapshot *ss)
	{
	int i;

	kfree(ss->reason);
	ss->reason = NULL;

	xe_guc_log_snapshot_free(ss->guc.log);
	ss->guc.log = NULL;

	xe_guc_ct_snapshot_free(ss->guc.ct);
	ss->guc.ct = NULL;

	xe_guc_capture_put_matched_nodes(&ss->gt->uc.guc);
	ss->matched_node = NULL;

	xe_guc_exec_queue_snapshot_free(ss->ge);
	ss->ge = NULL;

	xe_sched_job_snapshot_free(ss->job);
	ss->job = NULL;

	for (i = 0; i < XE_NUM_HW_ENGINES; i++)
	if (ss->hwe[i]) {
	xe_hw_engine_snapshot_free(ss->hwe[i]);
	ss->hwe[i] = NULL;
	}

	xe_vm_snapshot_free(ss->vm);
	ss->vm = NULL;
	}

	static ssize_t xe_devcoredump_read(char *buffer, loff_t offset,
	size_t count, void *data, size_t datalen)
	{
	struct xe_devcoredump *coredump = data;
	struct xe_devcoredump_snapshot *ss;
	ssize_t byte_copied;

	if (!coredump)
	return -ENODEV;

	ss = &coredump->snapshot;

	/* Ensure delayed work is captured before continuing */
	flush_work(&ss->work);

	mutex_lock(&coredump->lock);

	if (!ss->read.buffer) {
	mutex_unlock(&coredump->lock);
	return -ENODEV;
	}

	if (offset >= ss->read.size) {
	mutex_unlock(&coredump->lock);
	return 0;
	}

	byte_copied = count < ss->read.size - offset ? count :
	ss->read.size - offset;
	memcpy(buffer, ss->read.buffer + offset, byte_copied);

	mutex_unlock(&coredump->lock);

	return byte_copied;
	}

	static void xe_devcoredump_free(void *data)
	{
	struct xe_devcoredump *coredump = data;

	/* Our device is gone. Nothing to do... */
	if (!data \|\| !coredump_to_xe(coredump))
	return;

	cancel_work_sync(&coredump->snapshot.work);

	mutex_lock(&coredump->lock);

	xe_devcoredump_snapshot_free(&coredump->snapshot);
	kvfree(coredump->snapshot.read.buffer);

	/* To prevent stale data on next snapshot, clear everything */
	memset(&coredump->snapshot, 0, sizeof(coredump->snapshot));
	coredump->captured = false;
	drm_info(&coredump_to_xe(coredump)->drm,
	"Xe device coredump has been deleted.\n");

	mutex_unlock(&coredump->lock);
	}

	static void xe_devcoredump_deferred_snap_work(struct work_struct *work)
	{
	struct xe_devcoredump_snapshot ss = container_of(work, typeof(ss), work);
	struct xe_devcoredump coredump = container_of(ss, typeof(coredump), snapshot);
	struct xe_device *xe = coredump_to_xe(coredump);
	unsigned int fw_ref;

	/*
	* NB: Despite passing a GFP_ flags parameter here, more allocations are done
	* internally using GFP_KERNEL explicitly. Hence this call must be in the worker
	* thread and not in the initial capture call.
	*/
	dev_coredumpm_timeout(gt_to_xe(ss->gt)->drm.dev, THIS_MODULE, coredump, 0, GFP_KERNEL,
	xe_devcoredump_read, xe_devcoredump_free,
	XE_COREDUMP_TIMEOUT_JIFFIES);

	xe_pm_runtime_get(xe);

	/* keep going if fw fails as we still want to save the memory and SW data */
	fw_ref = xe_force_wake_get(gt_to_fw(ss->gt), XE_FORCEWAKE_ALL);
	if (!xe_force_wake_ref_has_domain(fw_ref, XE_FORCEWAKE_ALL))
	xe_gt_info(ss->gt, "failed to get forcewake for coredump capture\n");
	xe_vm_snapshot_capture_delayed(ss->vm);
	xe_guc_exec_queue_snapshot_capture_delayed(ss->ge);
	xe_force_wake_put(gt_to_fw(ss->gt), fw_ref);

	xe_pm_runtime_put(xe);

	/* Calculate devcoredump size */
	ss->read.size = __xe_devcoredump_read(NULL, INT_MAX, coredump);

	ss->read.buffer = kvmalloc(ss->read.size, GFP_USER);
	if (!ss->read.buffer)
	return;

	__xe_devcoredump_read(ss->read.buffer, ss->read.size, coredump);
	xe_devcoredump_snapshot_free(ss);
	}

	static void devcoredump_snapshot(struct xe_devcoredump *coredump,
	struct xe_exec_queue *q,
	struct xe_sched_job *job)
	{
	struct xe_devcoredump_snapshot *ss = &coredump->snapshot;
	struct xe_guc *guc = exec_queue_to_guc(q);
	u32 adj_logical_mask = q->logical_mask;
	u32 width_mask = (0x1 << q->width) - 1;
	const char *process_name = "no process";

	unsigned int fw_ref;
	bool cookie;
	int i;

	ss->snapshot_time = ktime_get_real();
	ss->boot_time = ktime_get_boottime();

	if (q->vm && q->vm->xef) {
	process_name = q->vm->xef->process_name;
	ss->pid = q->vm->xef->pid;
	}

	strscpy(ss->process_name, process_name);

	ss->gt = q->gt;
	INIT_WORK(&ss->work, xe_devcoredump_deferred_snap_work);

	cookie = dma_fence_begin_signalling();
	for (i = 0; q->width > 1 && i < XE_HW_ENGINE_MAX_INSTANCE;) {
	if (adj_logical_mask & BIT(i)) {
	adj_logical_mask \|= width_mask << i;
	i += q->width;
	} else {
	++i;
	}
	}

	/* keep going if fw fails as we still want to save the memory and SW data */
	fw_ref = xe_force_wake_get(gt_to_fw(q->gt), XE_FORCEWAKE_ALL);

	ss->guc.log = xe_guc_log_snapshot_capture(&guc->log, true);
	ss->guc.ct = xe_guc_ct_snapshot_capture(&guc->ct);
	ss->ge = xe_guc_exec_queue_snapshot_capture(q);
	if (job)
	ss->job = xe_sched_job_snapshot_capture(job);
	ss->vm = xe_vm_snapshot_capture(q->vm);

	xe_engine_snapshot_capture_for_queue(q);

	queue_work(system_unbound_wq, &ss->work);

	xe_force_wake_put(gt_to_fw(q->gt), fw_ref);
	dma_fence_end_signalling(cookie);
	}

	/**
	* xe_devcoredump - Take the required snapshots and initialize coredump device.
	* @q: The faulty xe_exec_queue, where the issue was detected.
	* @job: The faulty xe_sched_job, where the issue was detected.
	* @fmt: Printf format + args to describe the reason for the core dump
	*
	* This function should be called at the crash time within the serialized
	* gt_reset. It is skipped if we still have the core dump device available
	* with the information of the 'first' snapshot.
	*/
	__printf(3, 4)
	void xe_devcoredump(struct xe_exec_queue q, struct xe_sched_job job, const char *fmt, ...)
	{
	struct xe_device *xe = gt_to_xe(q->gt);
	struct xe_devcoredump *coredump = &xe->devcoredump;
	va_list varg;

	mutex_lock(&coredump->lock);

	if (coredump->captured) {
	drm_dbg(&xe->drm, "Multiple hangs are occurring, but only the first snapshot was taken\n");
	mutex_unlock(&coredump->lock);
	return;
	}

	coredump->captured = true;

	va_start(varg, fmt);
	coredump->snapshot.reason = kvasprintf(GFP_ATOMIC, fmt, varg);
	va_end(varg);

	devcoredump_snapshot(coredump, q, job);

	drm_info(&xe->drm, "Xe device coredump has been created\n");
	drm_info(&xe->drm, "Check your /sys/class/drm/card%d/device/devcoredump/data\n",
	xe->drm.primary->index);

	mutex_unlock(&coredump->lock);
	}

	static void xe_driver_devcoredump_fini(void *arg)
	{
	struct drm_device *drm = arg;

	dev_coredump_put(drm->dev);
	}

	int xe_devcoredump_init(struct xe_device *xe)
	{
	int err;

	err = drmm_mutex_init(&xe->drm, &xe->devcoredump.lock);
	if (err)
	return err;

	if (IS_ENABLED(CONFIG_LOCKDEP)) {
	fs_reclaim_acquire(GFP_KERNEL);
	might_lock(&xe->devcoredump.lock);
	fs_reclaim_release(GFP_KERNEL);
	}

	return devm_add_action_or_reset(xe->drm.dev, xe_driver_devcoredump_fini, &xe->drm);
	}

	#endif

	/**
	* xe_print_blob_ascii85 - print a BLOB to some useful location in ASCII85
	*
	* The output is split into multiple calls to drm_puts() because some print
	* targets, e.g. dmesg, cannot handle arbitrarily long lines. These targets may
	* add newlines, as is the case with dmesg: each drm_puts() call creates a
	* separate line.
	*
	* There is also a scheduler yield call to prevent the 'task has been stuck for
	* 120s' kernel hang check feature from firing when printing to a slow target
	* such as dmesg over a serial port.
	*
	* @p: the printer object to output to
	* @prefix: optional prefix to add to output string
	* @suffix: optional suffix to add at the end. 0 disables it and is
	* not added to the output, which is useful when using multiple calls
	* to dump data to @p
	* @blob: the Binary Large OBject to dump out
	* @offset: offset in bytes to skip from the front of the BLOB, must be a multiple of sizeof(u32)
	* @size: the size in bytes of the BLOB, must be a multiple of sizeof(u32)
	*/
	void xe_print_blob_ascii85(struct drm_printer p, const char prefix, char suffix,
	const void *blob, size_t offset, size_t size)
	{
	const u32 blob32 = (const u32 )blob;
	char buff[ASCII85_BUFSZ], *line_buff;
	size_t line_pos = 0;

	#define DMESG_MAX_LINE_LEN 800
	/* Always leave space for the suffix char and the \0 */
	#define MIN_SPACE (ASCII85_BUFSZ + 2) /* 85 + "<suffix>\0" */

	if (size & 3)
	drm_printf(p, "Size not word aligned: %zu", size);
	if (offset & 3)
	drm_printf(p, "Offset not word aligned: %zu", offset);

	line_buff = kzalloc(DMESG_MAX_LINE_LEN, GFP_KERNEL);
	if (!line_buff) {
	drm_printf(p, "Failed to allocate line buffer\n");
	return;
	}

	blob32 += offset / sizeof(*blob32);
	size /= sizeof(*blob32);

	if (prefix) {
	strscpy(line_buff, prefix, DMESG_MAX_LINE_LEN - MIN_SPACE - 2);
	line_pos = strlen(line_buff);

	line_buff[line_pos++] = ':';
	line_buff[line_pos++] = ' ';
	}

	while (size--) {
	u32 val = *(blob32++);

	strscpy(line_buff + line_pos, ascii85_encode(val, buff),
	DMESG_MAX_LINE_LEN - line_pos);
	line_pos += strlen(line_buff + line_pos);

	if ((line_pos + MIN_SPACE) >= DMESG_MAX_LINE_LEN) {
	line_buff[line_pos++] = 0;

	drm_puts(p, line_buff);

	line_pos = 0;

	/* Prevent 'stuck thread' time out errors */
	cond_resched();
	}
	}

	if (suffix)
	line_buff[line_pos++] = suffix;

	if (line_pos) {
	line_buff[line_pos++] = 0;
	drm_puts(p, line_buff);
	}

	kfree(line_buff);

	#undef MIN_SPACE
	#undef DMESG_MAX_LINE_LEN
	}