diff mbox series

[v17,02/18] EDAC: Add scrub control feature

Message ID 20241122180416.1932-3-shiju.jose@huawei.com (mailing list archive)
State New
Headers show
Series EDAC: Scrub: introduce generic EDAC RAS control feature driver + CXL/ACPI-RAS2 drivers | expand

Commit Message

Shiju Jose Nov. 22, 2024, 6:03 p.m. UTC
From: Shiju Jose <shiju.jose@huawei.com>

Add a generic EDAC scrub control to manage memory scrubbers in the system.
Devices with a scrub feature register with the EDAC device driver, which
retrieves the scrub descriptor from the EDAC scrub driver and exposes the
sysfs scrub control attributes for a scrub instance to userspace at
/sys/bus/edac/devices/<dev-name>/scrubX/.

The common sysfs scrub control interface abstracts the control of
arbitrary scrubbing functionality into a common set of functions. The
sysfs scrub attribute nodes are only present if the client driver has
implemented the corresponding attribute callback function and passed the
operations(ops) to the EDAC device driver during registration.

Co-developed-by: Jonathan Cameron <Jonathan.Cameron@huawei.com>
Signed-off-by: Jonathan Cameron <Jonathan.Cameron@huawei.com>
Signed-off-by: Shiju Jose <shiju.jose@huawei.com>
---
 Documentation/ABI/testing/sysfs-edac-scrub |  74 +++++++
 Documentation/edac/features.rst            |   5 +
 Documentation/edac/index.rst               |   1 +
 Documentation/edac/scrub.rst               | 244 +++++++++++++++++++++
 drivers/edac/Makefile                      |   1 +
 drivers/edac/edac_device.c                 |  41 +++-
 drivers/edac/scrub.c                       | 209 ++++++++++++++++++
 include/linux/edac.h                       |  34 +++
 8 files changed, 605 insertions(+), 4 deletions(-)
 create mode 100644 Documentation/ABI/testing/sysfs-edac-scrub
 create mode 100644 Documentation/edac/scrub.rst
 create mode 100755 drivers/edac/scrub.c
diff mbox series

Patch

diff --git a/Documentation/ABI/testing/sysfs-edac-scrub b/Documentation/ABI/testing/sysfs-edac-scrub
new file mode 100644
index 000000000000..d8d11165ff2a
--- /dev/null
+++ b/Documentation/ABI/testing/sysfs-edac-scrub
@@ -0,0 +1,74 @@ 
+What:		/sys/bus/edac/devices/<dev-name>/scrubX
+Date:		Jan 2025
+KernelVersion:	6.13
+Contact:	linux-edac@vger.kernel.org
+Description:
+		The sysfs EDAC bus devices /<dev-name>/scrubX subdirectory
+		belongs to an instance of memory scrub control feature,
+		where <dev-name> directory corresponds to a device/memory
+		region registered with the EDAC device driver for the
+		scrub control feature.
+		The sysfs scrub attr nodes are only present if the parent
+		driver has implemented the corresponding attr callback
+		function and provided the necessary operations to the EDAC
+		device driver during registration.
+
+What:		/sys/bus/edac/devices/<dev-name>/scrubX/addr
+Date:		Jan 2025
+KernelVersion:	6.13
+Contact:	linux-edac@vger.kernel.org
+Description:
+		(RW) The base address of the memory region to be scrubbed
+		for on-demand scrubbing. Setting address would start
+		scrubbing. The size must be set before that.
+		The readback addr value would be non-zero if the requested
+		on-demand scrubbing is in progress, zero otherwise.
+
+What:		/sys/bus/edac/devices/<dev-name>/scrubX/size
+Date:		Jan 2025
+KernelVersion:	6.13
+Contact:	linux-edac@vger.kernel.org
+Description:
+		(RW) The size of the memory region to be scrubbed
+		(on-demand scrubbing).
+
+What:		/sys/bus/edac/devices/<dev-name>/scrubX/enable_background
+Date:		Jan 2025
+KernelVersion:	6.13
+Contact:	linux-edac@vger.kernel.org
+Description:
+		(RW) Start/Stop background(patrol) scrubbing if supported.
+
+What:		/sys/bus/edac/devices/<dev-name>/scrubX/enable_on_demand
+Date:		Jan 2025
+KernelVersion:	6.13
+Contact:	linux-edac@vger.kernel.org
+Description:
+		(RW) Start/Stop on-demand scrubbing the memory region
+		if supported.
+
+What:		/sys/bus/edac/devices/<dev-name>/scrubX/min_cycle_duration
+Date:		Jan 2025
+KernelVersion:	6.13
+Contact:	linux-edac@vger.kernel.org
+Description:
+		(RO) Supported minimum scrub cycle duration in seconds
+		by the memory scrubber.
+
+What:		/sys/bus/edac/devices/<dev-name>/scrubX/max_cycle_duration
+Date:		Jan 2025
+KernelVersion:	6.13
+Contact:	linux-edac@vger.kernel.org
+Description:
+		(RO) Supported maximum scrub cycle duration in seconds
+		by the memory scrubber.
+
+What:		/sys/bus/edac/devices/<dev-name>/scrubX/current_cycle_duration
+Date:		Jan 2025
+KernelVersion:	6.13
+Contact:	linux-edac@vger.kernel.org
+Description:
+		(RW) The current scrub cycle duration in seconds and must be
+		within the supported range by the memory scrubber.
+		Scrub has an overhead when running and that may want to be
+		reduced by taking longer to do it.
diff --git a/Documentation/edac/features.rst b/Documentation/edac/features.rst
index e7a63146e708..4c3c190a3e48 100644
--- a/Documentation/edac/features.rst
+++ b/Documentation/edac/features.rst
@@ -92,3 +92,8 @@  the sysfs EDAC bus. For example, /sys/bus/edac/devices/<dev-name>/<feature>X/
 3. RAS dynamic feature controller - Userspace sample modules in rasdaemon for
 dynamic scrub/repair control to issue scrubbing/repair when excess number
 of corrected memory errors are reported in a short span of time.
+
+RAS features
+------------
+1. Memory Scrub
+Memory scrub features are documented in `Documentation/edac/scrub.rst`.
diff --git a/Documentation/edac/index.rst b/Documentation/edac/index.rst
index b6c265a4cffb..dfb0c9fb9ab1 100644
--- a/Documentation/edac/index.rst
+++ b/Documentation/edac/index.rst
@@ -8,3 +8,4 @@  EDAC Subsystem
    :maxdepth: 1
 
    features
+   scrub
diff --git a/Documentation/edac/scrub.rst b/Documentation/edac/scrub.rst
new file mode 100644
index 000000000000..3d3af8bdacd3
--- /dev/null
+++ b/Documentation/edac/scrub.rst
@@ -0,0 +1,244 @@ 
+.. SPDX-License-Identifier: GPL-2.0
+
+===================
+EDAC Scrub Control
+===================
+
+Copyright (c) 2024 HiSilicon Limited.
+
+:Author:   Shiju Jose <shiju.jose@huawei.com>
+:License:  The GNU Free Documentation License, Version 1.2
+          (dual licensed under the GPL v2)
+:Original Reviewers:
+
+- Written for: 6.13
+
+Introduction
+------------
+Increasing DRAM size and cost have made memory subsystem reliability an
+important concern. These modules are used where potentially corrupted data
+could cause expensive or fatal issues. Memory errors are among the top
+hardware failures that cause server and workload crashes.
+
+Memory scrubbing is a feature where an ECC (Error-Correcting Code) engine
+reads data from each memory media location, corrects with an ECC if
+necessary and writes the corrected data back to the same memory media
+location.
+
+The memory DIMMs can be scrubbed at a configurable rate to detect
+uncorrected memory errors and attempt recovery from detected errors,
+providing the following benefits.
+
+* Proactively scrubbing memory DIMMs reduces the chance of a correctable error becoming uncorrectable.
+
+* When detected, uncorrected errors caught in unallocated memory pages are isolated and prevented from being allocated to an application or the OS.
+
+* This reduces the likelihood of software or hardware products encountering memory errors.
+
+There are 2 types of memory scrubbing:
+
+1. Background (patrol) scrubbing of the RAM while the RAM is otherwise
+idle.
+
+2. On-demand scrubbing for a specific address range or region of memory.
+
+Several types of interfaces to hardware memory scrubbers have been
+identified, such as CXL memory device patrol scrub, CXL DDR5 ECS, ACPI
+RAS2 memory scrubbing, and ACPI NVDIMM ARS (Address Range Scrub).
+
+The scrub control varies between different memory scrubbers. To allow
+for standard userspace tooling there is a need to present these controls
+with a standard ABI.
+
+The control mechanisms vary across different memory scrubbers. To enable
+standardized userspace tooling, there is a need to present these controls
+through a standardized ABI.
+
+Introduce a generic memory EDAC scrub control that allows users to manage
+underlying scrubbers in the system through a standardized sysfs scrub
+control interface. This common sysfs scrub control interface abstracts the
+management of various scrubbing functionalities into a unified set of
+functions.
+
+Use cases of common scrub control feature
+-----------------------------------------
+1. Several types of interfaces for hardware (HW) memory scrubbers have
+been identified, including the CXL memory device patrol scrub, CXL DDR5
+ECS, ACPI RAS2 memory scrubbing features, ACPI NVDIMM ARS (Address Range
+Scrub), and software-based memory scrubbers. Some of these scrubbers
+support control over patrol (background) scrubbing (e.g., ACPI RAS2, CXL)
+and/or on-demand scrubbing (e.g., ACPI RAS2, ACPI ARS). However, the scrub
+control interfaces vary between memory scrubbers, highlighting the need for
+a standardized, generic sysfs scrub control interface that is accessible to
+userspace for administration and use by scripts/tools.
+
+2. User-space scrub controls allow users to disable scrubbing if necessary,
+for example, to disable background patrol scrubbing or adjust the scrub
+rate for performance-aware operations where background activities need to
+be minimized or disabled.
+
+3. User-space tools enable on-demand scrubbing for specific address ranges,
+provided that the scrubber supports this functionality.
+
+4. User-space tools can also control memory DIMM scrubbing at a configurable
+scrub rate via sysfs scrub controls. This approach offers several benefits:
+
+* Detects uncorrectable memory errors early, before user access to affected memory, helping facilitate recovery.
+
+* Reduces the likelihood of correctable errors developing into uncorrectable errors.
+
+5. Policy control for hotplugged memory is necessary because there may not
+be a system-wide BIOS or similar control to manage scrub settings for a CXL
+device added after boot. Determining these settings is a policy decision,
+balancing reliability against performance, so userspace should control it.
+Therefore, a unified interface is recommended for handling this function in
+a way that aligns with other similar interfaces, rather than creating a
+separate one.
+
+Scrubbing features
+------------------
+Comparison of various scrubbing features::
+
+ ................................................................
+ .              .   ACPI    . CXL patrol.  CXL ECS  .  ARS      .
+ .  Name        .   RAS2    . scrub     .           .           .
+ ................................................................
+ .              .           .           .           .           .
+ . On-demand    . Supported . No        . No        . Supported .
+ . Scrubbing    .           .           .           .           .
+ .              .           .           .           .           .
+ ................................................................
+ .              .           .           .           .           .
+ . Background   . Supported . Supported . Supported . No        .
+ . scrubbing    .           .           .           .           .
+ .              .           .           .           .           .
+ ................................................................
+ .              .           .           .           .           .
+ . Mode of      . Scrub ctrl. per device. per memory.  Unknown  .
+ . scrubbing    . per NUMA  .           . media     .           .
+ .              . domain.   .           .           .           .
+ ................................................................
+ .              .           .           .           .           .
+ . Query scrub  . Supported . Supported . Supported . Supported .
+ . capabilities .           .           .           .           .
+ .              .           .           .           .           .
+ ................................................................
+ .              .           .           .           .           .
+ . Setting      . Supported . No        . No        . Supported .
+ . address range.           .           .           .           .
+ .              .           .           .           .           .
+ ................................................................
+ .              .           .           .           .           .
+ . Setting      . Supported . Supported . No        . No        .
+ . scrub rate   .           .           .           .           .
+ .              .           .           .           .           .
+ ................................................................
+ .              .           .           .           .           .
+ . Unit for     . Not       . in hours  . No        . No        .
+ . scrub rate   . Defined   .           .           .           .
+ .              .           .           .           .           .
+ ................................................................
+ .              . Supported .           .           .           .
+ . Scrub        . on-demand . No        . No        . Supported .
+ . status/      . scrubbing .           .           .           .
+ . Completion   . only      .           .           .           .
+ ................................................................
+ . UC error     .           .CXL general.CXL general. ACPI UCE  .
+ . reporting    . Exception .media/DRAM .media/DRAM . notify and.
+ .              .           .event/media.event/media. query     .
+ .              .           .scan?      .scan?      . ARS status.
+ ................................................................
+ .              .           .           .           .           .
+ . Support for  . Supported . Supported . Supported . No        .
+ . EDAC control .           .           .           .           .
+ .              .           .           .           .           .
+ ................................................................
+
+CXL Memory Scrubbing features
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+CXL spec r3.1 section 8.2.9.9.11.1 describes the memory device patrol scrub
+control feature. The device patrol scrub proactively locates and makes
+corrections to errors in regular cycle. The patrol scrub control allows the
+request to configure patrol scrubber's input configurations.
+
+The patrol scrub control allows the requester to specify the number of
+hours in which the patrol scrub cycles must be completed, provided that
+the requested number is not less than the minimum number of hours for the
+patrol scrub cycle that the device is capable of. In addition, the patrol
+scrub controls allow the host to disable and enable the feature in case
+disabling of the feature is needed for other purposes such as
+performance-aware operations which require the background operations to be
+turned off.
+
+Error Check Scrub (ECS)
+~~~~~~~~~~~~~~~~~~~~~~~
+CXL spec r3.1 section 8.2.9.9.11.2 describes the Error Check Scrub (ECS)
+is a feature defined in JEDEC DDR5 SDRAM Specification (JESD79-5) and
+allows the DRAM to internally read, correct single-bit errors, and write
+back corrected data bits to the DRAM array while providing transparency
+to error counts.
+
+The DDR5 device contains number of memory media FRUs per device. The
+DDR5 ECS feature and thus the ECS control driver supports configuring
+the ECS parameters per FRU.
+
+ACPI RAS2 Hardware-based Memory Scrubbing
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+ACPI spec 6.5 section 5.2.21 ACPI RAS2 describes ACPI RAS2 table
+provides interfaces for platform RAS features and supports independent
+RAS controls and capabilities for a given RAS feature for multiple
+instances of the same component in a given system.
+Memory RAS features apply to RAS capabilities, controls and operations
+that are specific to memory. RAS2 PCC sub-spaces for memory-specific RAS
+features have a Feature Type of 0x00 (Memory).
+
+The platform can use the hardware-based memory scrubbing feature to expose
+controls and capabilities associated with hardware-based memory scrub
+engines. The RAS2 memory scrubbing feature supports following as per spec,
+
+* Independent memory scrubbing controls for each NUMA domain, identified using its proximity domain.
+
+* Provision for background (patrol) scrubbing of the entire memory system, as well as on-demand scrubbing for a specific region of memory.
+
+ACPI Address Range Scrubbing(ARS)
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+ACPI spec 6.5 section 9.19.7.2 describes Address Range Scrubbing(ARS).
+ARS allows the platform to communicate memory errors to system software.
+This capability allows system software to prevent accesses to addresses
+with uncorrectable errors in memory. ARS functions manage all NVDIMMs
+present in the system. Only one scrub can be in progress system wide
+at any given time.
+Following functions are supported as per the specification.
+
+1. Query ARS Capabilities for a given address range, indicates platform
+supports the ACPI NVDIMM Root Device Unconsumed Error Notification.
+
+2. Start ARS triggers an Address Range Scrub for the given memory range.
+Address scrubbing can be done for volatile memory, persistent memory, or both.
+
+3. Query ARS Status command allows software to get the status of ARS,
+including the progress of ARS and ARS error record.
+
+4. Clear Uncorrectable Error.
+
+5. Translate SPA
+
+6. ARS Error Inject etc.
+
+The kernel supports an existing control for ARS and ARS is currently not
+supported in EDAC.
+
+The File System
+---------------
+
+The control attributes of a registered scrubber instance could be
+accessed in the
+
+/sys/bus/edac/devices/<dev-name>/scrubX/
+
+sysfs
+-----
+
+Sysfs files are documented in
+
+`Documentation/ABI/testing/sysfs-edac-scrub`.
diff --git a/drivers/edac/Makefile b/drivers/edac/Makefile
index faf310eec4a6..188501e676c7 100644
--- a/drivers/edac/Makefile
+++ b/drivers/edac/Makefile
@@ -10,6 +10,7 @@  obj-$(CONFIG_EDAC)			:= edac_core.o
 
 edac_core-y	:= edac_mc.o edac_device.o edac_mc_sysfs.o
 edac_core-y	+= edac_module.o edac_device_sysfs.o wq.o
+edac_core-y	+= scrub.o
 
 edac_core-$(CONFIG_EDAC_DEBUG)		+= debugfs.o
 
diff --git a/drivers/edac/edac_device.c b/drivers/edac/edac_device.c
index 9fce46dd7405..60b20eae01e8 100644
--- a/drivers/edac/edac_device.c
+++ b/drivers/edac/edac_device.c
@@ -575,6 +575,7 @@  static void edac_dev_release(struct device *dev)
 {
 	struct edac_dev_feat_ctx *ctx = container_of(dev, struct edac_dev_feat_ctx, dev);
 
+	kfree(ctx->scrub);
 	kfree(ctx->dev.groups);
 	kfree(ctx);
 }
@@ -608,8 +609,10 @@  int edac_dev_register(struct device *parent, char *name,
 		      const struct edac_dev_feature *ras_features)
 {
 	const struct attribute_group **ras_attr_groups;
+	struct edac_dev_data *dev_data;
 	struct edac_dev_feat_ctx *ctx;
 	int attr_gcnt = 0;
+	int scrub_cnt = 0;
 	int ret, feat;
 
 	if (!parent || !name || !num_features || !ras_features)
@@ -618,7 +621,10 @@  int edac_dev_register(struct device *parent, char *name,
 	/* Double parse to make space for attributes */
 	for (feat = 0; feat < num_features; feat++) {
 		switch (ras_features[feat].ft_type) {
-		/* Add feature specific code */
+		case RAS_FEAT_SCRUB:
+			attr_gcnt++;
+			scrub_cnt++;
+			break;
 		default:
 			return -EINVAL;
 		}
@@ -634,13 +640,38 @@  int edac_dev_register(struct device *parent, char *name,
 		goto ctx_free;
 	}
 
+	if (scrub_cnt) {
+		ctx->scrub = kcalloc(scrub_cnt, sizeof(*ctx->scrub), GFP_KERNEL);
+		if (!ctx->scrub) {
+			ret = -ENOMEM;
+			goto groups_free;
+		}
+	}
+
 	attr_gcnt = 0;
+	scrub_cnt = 0;
 	for (feat = 0; feat < num_features; feat++, ras_features++) {
 		switch (ras_features->ft_type) {
-		/* Add feature specific code */
+		case RAS_FEAT_SCRUB:
+			if (!ras_features->scrub_ops ||
+			    scrub_cnt != ras_features->instance)
+				goto data_mem_free;
+
+			dev_data = &ctx->scrub[scrub_cnt];
+			dev_data->instance = scrub_cnt;
+			dev_data->scrub_ops = ras_features->scrub_ops;
+			dev_data->private = ras_features->ctx;
+			ret = edac_scrub_get_desc(parent, &ras_attr_groups[attr_gcnt],
+						  ras_features->instance);
+			if (ret)
+				goto data_mem_free;
+
+			scrub_cnt++;
+			attr_gcnt++;
+			break;
 		default:
 			ret = -EINVAL;
-			goto groups_free;
+			goto data_mem_free;
 		}
 	}
 
@@ -653,7 +684,7 @@  int edac_dev_register(struct device *parent, char *name,
 
 	ret = dev_set_name(&ctx->dev, name);
 	if (ret)
-		goto groups_free;
+		goto data_mem_free;
 
 	ret = device_register(&ctx->dev);
 	if (ret) {
@@ -663,6 +694,8 @@  int edac_dev_register(struct device *parent, char *name,
 
 	return devm_add_action_or_reset(parent, edac_dev_unreg, &ctx->dev);
 
+data_mem_free:
+	kfree(ctx->scrub);
 groups_free:
 	kfree(ras_attr_groups);
 ctx_free:
diff --git a/drivers/edac/scrub.c b/drivers/edac/scrub.c
new file mode 100755
index 000000000000..3978201c4bfc
--- /dev/null
+++ b/drivers/edac/scrub.c
@@ -0,0 +1,209 @@ 
+// SPDX-License-Identifier: GPL-2.0
+/*
+ * The generic EDAC scrub driver controls the memory scrubbers in the
+ * system. The common sysfs scrub interface abstracts the control of
+ * various arbitrary scrubbing functionalities into a unified set of
+ * functions.
+ *
+ * Copyright (c) 2024 HiSilicon Limited.
+ */
+
+#include <linux/edac.h>
+
+enum edac_scrub_attributes {
+	SCRUB_ADDRESS,
+	SCRUB_SIZE,
+	SCRUB_ENABLE_BACKGROUND,
+	SCRUB_MIN_CYCLE_DURATION,
+	SCRUB_MAX_CYCLE_DURATION,
+	SCRUB_CUR_CYCLE_DURATION,
+	SCRUB_MAX_ATTRS
+};
+
+struct edac_scrub_dev_attr {
+	struct device_attribute dev_attr;
+	u8 instance;
+};
+
+struct edac_scrub_context {
+	char name[EDAC_FEAT_NAME_LEN];
+	struct edac_scrub_dev_attr scrub_dev_attr[SCRUB_MAX_ATTRS];
+	struct attribute *scrub_attrs[SCRUB_MAX_ATTRS + 1];
+	struct attribute_group group;
+};
+
+#define TO_SCRUB_DEV_ATTR(_dev_attr)      \
+		container_of(_dev_attr, struct edac_scrub_dev_attr, dev_attr)
+
+#define EDAC_SCRUB_ATTR_SHOW(attrib, cb, type, format)				\
+static ssize_t attrib##_show(struct device *ras_feat_dev,			\
+			     struct device_attribute *attr, char *buf)		\
+{										\
+	u8 inst = TO_SCRUB_DEV_ATTR(attr)->instance;				\
+	struct edac_dev_feat_ctx *ctx = dev_get_drvdata(ras_feat_dev);		\
+	const struct edac_scrub_ops *ops = ctx->scrub[inst].scrub_ops;		\
+	type data;								\
+	int ret;								\
+										\
+	ret = ops->cb(ras_feat_dev->parent, ctx->scrub[inst].private, &data);	\
+	if (ret)								\
+		return ret;							\
+										\
+	return sysfs_emit(buf, format, data);					\
+}
+
+EDAC_SCRUB_ATTR_SHOW(addr, read_addr, u64, "0x%llx\n")
+EDAC_SCRUB_ATTR_SHOW(size, read_size, u64, "0x%llx\n")
+EDAC_SCRUB_ATTR_SHOW(enable_background, get_enabled_bg, bool, "%u\n")
+EDAC_SCRUB_ATTR_SHOW(min_cycle_duration, get_min_cycle, u32, "%u\n")
+EDAC_SCRUB_ATTR_SHOW(max_cycle_duration, get_max_cycle, u32, "%u\n")
+EDAC_SCRUB_ATTR_SHOW(current_cycle_duration, get_cycle_duration, u32, "%u\n")
+
+#define EDAC_SCRUB_ATTR_STORE(attrib, cb, type, conv_func)			\
+static ssize_t attrib##_store(struct device *ras_feat_dev,			\
+			      struct device_attribute *attr,			\
+			      const char *buf, size_t len)			\
+{										\
+	u8 inst = TO_SCRUB_DEV_ATTR(attr)->instance;				\
+	struct edac_dev_feat_ctx *ctx = dev_get_drvdata(ras_feat_dev);		\
+	const struct edac_scrub_ops *ops = ctx->scrub[inst].scrub_ops;		\
+	type data;								\
+	int ret;								\
+										\
+	ret = conv_func(buf, 0, &data);						\
+	if (ret < 0)								\
+		return ret;							\
+										\
+	ret = ops->cb(ras_feat_dev->parent, ctx->scrub[inst].private, data);	\
+	if (ret)								\
+		return ret;							\
+										\
+	return len;								\
+}
+
+EDAC_SCRUB_ATTR_STORE(addr, write_addr, u64, kstrtou64)
+EDAC_SCRUB_ATTR_STORE(size, write_size, u64, kstrtou64)
+EDAC_SCRUB_ATTR_STORE(enable_background, set_enabled_bg, unsigned long, kstrtoul)
+EDAC_SCRUB_ATTR_STORE(current_cycle_duration, set_cycle_duration, unsigned long, kstrtoul)
+
+static umode_t scrub_attr_visible(struct kobject *kobj, struct attribute *a, int attr_id)
+{
+	struct device *ras_feat_dev = kobj_to_dev(kobj);
+	struct device_attribute *dev_attr = container_of(a, struct device_attribute, attr);
+	u8 inst = TO_SCRUB_DEV_ATTR(dev_attr)->instance;
+	struct edac_dev_feat_ctx *ctx = dev_get_drvdata(ras_feat_dev);
+	const struct edac_scrub_ops *ops = ctx->scrub[inst].scrub_ops;
+
+	switch (attr_id) {
+	case SCRUB_ADDRESS:
+		if (ops->read_addr) {
+			if (ops->write_addr)
+				return a->mode;
+			else
+				return 0444;
+		}
+		break;
+	case SCRUB_SIZE:
+		if (ops->read_size) {
+			if (ops->write_size)
+				return a->mode;
+			else
+				return 0444;
+		}
+		break;
+	case SCRUB_ENABLE_BACKGROUND:
+		if (ops->get_enabled_bg) {
+			if (ops->set_enabled_bg)
+				return a->mode;
+			else
+				return 0444;
+		}
+		break;
+	case SCRUB_MIN_CYCLE_DURATION:
+		if (ops->get_min_cycle)
+			return a->mode;
+		break;
+	case SCRUB_MAX_CYCLE_DURATION:
+		if (ops->get_max_cycle)
+			return a->mode;
+		break;
+	case SCRUB_CUR_CYCLE_DURATION:
+		if (ops->get_cycle_duration) {
+			if (ops->set_cycle_duration)
+				return a->mode;
+			else
+				return 0444;
+		}
+		break;
+	default:
+		break;
+	}
+
+	return 0;
+}
+
+#define EDAC_SCRUB_ATTR_RO(_name, _instance)       \
+	((struct edac_scrub_dev_attr) { .dev_attr = __ATTR_RO(_name), \
+					.instance = _instance })
+
+#define EDAC_SCRUB_ATTR_WO(_name, _instance)       \
+	((struct edac_scrub_dev_attr) { .dev_attr = __ATTR_WO(_name), \
+					.instance = _instance })
+
+#define EDAC_SCRUB_ATTR_RW(_name, _instance)       \
+	((struct edac_scrub_dev_attr) { .dev_attr = __ATTR_RW(_name), \
+					.instance = _instance })
+
+static int scrub_create_desc(struct device *scrub_dev,
+			     const struct attribute_group **attr_groups, u8 instance)
+{
+	struct edac_scrub_context *scrub_ctx;
+	struct attribute_group *group;
+	int i;
+	struct edac_scrub_dev_attr dev_attr[] = {
+		[SCRUB_ADDRESS] = EDAC_SCRUB_ATTR_RW(addr, instance),
+		[SCRUB_SIZE] = EDAC_SCRUB_ATTR_RW(size, instance),
+		[SCRUB_ENABLE_BACKGROUND] = EDAC_SCRUB_ATTR_RW(enable_background, instance),
+		[SCRUB_MIN_CYCLE_DURATION] = EDAC_SCRUB_ATTR_RO(min_cycle_duration, instance),
+		[SCRUB_MAX_CYCLE_DURATION] = EDAC_SCRUB_ATTR_RO(max_cycle_duration, instance),
+		[SCRUB_CUR_CYCLE_DURATION] = EDAC_SCRUB_ATTR_RW(current_cycle_duration, instance)
+	};
+
+	scrub_ctx = devm_kzalloc(scrub_dev, sizeof(*scrub_ctx), GFP_KERNEL);
+	if (!scrub_ctx)
+		return -ENOMEM;
+
+	group = &scrub_ctx->group;
+	for (i = 0; i < SCRUB_MAX_ATTRS; i++) {
+		memcpy(&scrub_ctx->scrub_dev_attr[i], &dev_attr[i], sizeof(dev_attr[i]));
+		scrub_ctx->scrub_attrs[i] = &scrub_ctx->scrub_dev_attr[i].dev_attr.attr;
+	}
+	sprintf(scrub_ctx->name, "%s%d", "scrub", instance);
+	group->name = scrub_ctx->name;
+	group->attrs = scrub_ctx->scrub_attrs;
+	group->is_visible  = scrub_attr_visible;
+
+	attr_groups[0] = group;
+
+	return 0;
+}
+
+/**
+ * edac_scrub_get_desc - get EDAC scrub descriptors
+ * @scrub_dev: client device, with scrub support
+ * @attr_groups: pointer to attribute group container
+ * @instance: device's scrub instance number.
+ *
+ * Return:
+ *  * %0	- Success.
+ *  * %-EINVAL	- Invalid parameters passed.
+ *  * %-ENOMEM	- Dynamic memory allocation failed.
+ */
+int edac_scrub_get_desc(struct device *scrub_dev,
+			const struct attribute_group **attr_groups, u8 instance)
+{
+	if (!scrub_dev || !attr_groups)
+		return -EINVAL;
+
+	return scrub_create_desc(scrub_dev, attr_groups, instance);
+}
diff --git a/include/linux/edac.h b/include/linux/edac.h
index 521b17113d4d..ace8b10bb028 100644
--- a/include/linux/edac.h
+++ b/include/linux/edac.h
@@ -666,11 +666,43 @@  static inline struct dimm_info *edac_get_dimm(struct mem_ctl_info *mci,
 
 /* RAS feature type */
 enum edac_dev_feat {
+	RAS_FEAT_SCRUB,
 	RAS_FEAT_MAX
 };
 
+/**
+ * struct edac_scrub_ops - scrub device operations (all elements optional)
+ * @read_addr: read base address of scrubbing range.
+ * @read_size: read offset of scrubbing range.
+ * @write_addr: set base address of the scrubbing range.
+ * @write_size: set offset of the scrubbing range.
+ * @get_enabled_bg: check if currently performing background scrub.
+ * @set_enabled_bg: start or stop a bg-scrub.
+ * @get_min_cycle: get minimum supported scrub cycle duration in seconds.
+ * @get_max_cycle: get maximum supported scrub cycle duration in seconds.
+ * @get_cycle_duration: get current scrub cycle duration in seconds.
+ * @set_cycle_duration: set current scrub cycle duration in seconds.
+ */
+struct edac_scrub_ops {
+	int (*read_addr)(struct device *dev, void *drv_data, u64 *base);
+	int (*read_size)(struct device *dev, void *drv_data, u64 *size);
+	int (*write_addr)(struct device *dev, void *drv_data, u64 base);
+	int (*write_size)(struct device *dev, void *drv_data, u64 size);
+	int (*get_enabled_bg)(struct device *dev, void *drv_data, bool *enable);
+	int (*set_enabled_bg)(struct device *dev, void *drv_data, bool enable);
+	int (*get_min_cycle)(struct device *dev, void *drv_data,  u32 *min);
+	int (*get_max_cycle)(struct device *dev, void *drv_data,  u32 *max);
+	int (*get_cycle_duration)(struct device *dev, void *drv_data, u32 *cycle);
+	int (*set_cycle_duration)(struct device *dev, void *drv_data, u32 cycle);
+};
+
+int edac_scrub_get_desc(struct device *scrub_dev,
+			const struct attribute_group **attr_groups,
+			u8 instance);
+
 /* EDAC device feature information structure */
 struct edac_dev_data {
+	const struct edac_scrub_ops *scrub_ops;
 	u8 instance;
 	void *private;
 };
@@ -678,11 +710,13 @@  struct edac_dev_data {
 struct edac_dev_feat_ctx {
 	struct device dev;
 	void *private;
+	struct edac_dev_data *scrub;
 };
 
 struct edac_dev_feature {
 	enum edac_dev_feat ft_type;
 	u8 instance;
+	const struct edac_scrub_ops *scrub_ops;
 	void *ctx;
 };