From patchwork Wed Oct 9 12:41:01 2024 Content-Type: text/plain; charset="utf-8" MIME-Version: 1.0 Content-Transfer-Encoding: 7bit X-Patchwork-Submitter: Shiju Jose X-Patchwork-Id: 13828332 Received: from frasgout.his.huawei.com (frasgout.his.huawei.com [185.176.79.56]) (using TLSv1.2 with cipher ECDHE-RSA-AES256-GCM-SHA384 (256/256 bits)) (No client certificate requested) by smtp.subspace.kernel.org (Postfix) with ESMTPS id 07DFC194ACA; Wed, 9 Oct 2024 12:43:03 +0000 (UTC) Authentication-Results: smtp.subspace.kernel.org; arc=none smtp.client-ip=185.176.79.56 ARC-Seal: i=1; a=rsa-sha256; d=subspace.kernel.org; s=arc-20240116; t=1728477787; cv=none; b=IPYGXklcAFVcRsGneJj+IPvQDY4TepGbfvhOGi8kc8HrGBo/LQCY6gYcsOg7Mw3uQyxoKQKS9QaQrFSt36GYqvOmU2aDyLc1IkAbedOR4sJZCO3eh6MzbZfzUsAWFr4yoGbC3m0Xee1AhRlRVmk84D/W/SwrqUMl1Q95kZkY5NU= ARC-Message-Signature: i=1; a=rsa-sha256; d=subspace.kernel.org; s=arc-20240116; t=1728477787; c=relaxed/simple; bh=as+TOkohnTh4V3rOotkASoNCEloQt+8p6UiDP4WEGHA=; h=From:To:CC:Subject:Date:Message-ID:MIME-Version:Content-Type; b=i4I4YCisQFgVsJ8vRRclAaxHU2A2bbEqjjbHfYtOuL5H3joRPeKxy7ZZ+opQSjkg0AqVpWWyq+sX76gACOZjSXmXGLbECepSXNyF61BbKTd7hHBeHe4gADYkfEMpz4NngsXU2CEE+aozzFavw6WaSf1u4wrc6Aj2D0KyTSe0bew= ARC-Authentication-Results: i=1; smtp.subspace.kernel.org; dmarc=pass (p=quarantine dis=none) header.from=huawei.com; spf=pass smtp.mailfrom=huawei.com; arc=none smtp.client-ip=185.176.79.56 Authentication-Results: smtp.subspace.kernel.org; dmarc=pass (p=quarantine dis=none) header.from=huawei.com Authentication-Results: smtp.subspace.kernel.org; spf=pass smtp.mailfrom=huawei.com Received: from mail.maildlp.com (unknown [172.18.186.231]) by frasgout.his.huawei.com (SkyGuard) with ESMTP id 4XNswz10cYz6GD5T; Wed, 9 Oct 2024 20:42:43 +0800 (CST) Received: from frapeml500007.china.huawei.com (unknown [7.182.85.172]) by mail.maildlp.com (Postfix) with ESMTPS id D8A64140B3C; Wed, 9 Oct 2024 20:43:00 +0800 (CST) Received: from P_UKIT01-A7bmah.china.huawei.com (10.48.152.209) by frapeml500007.china.huawei.com (7.182.85.172) with Microsoft SMTP Server (version=TLS1_2, cipher=TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384) id 15.1.2507.39; Wed, 9 Oct 2024 14:42:58 +0200 From: To: , , , , CC: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , Subject: [PATCH v13 00/18] EDAC: Scrub: introduce generic EDAC RAS control feature driver + CXL/ACPI-RAS2 drivers Date: Wed, 9 Oct 2024 13:41:01 +0100 Message-ID: <20241009124120.1124-1-shiju.jose@huawei.com> X-Mailer: git-send-email 2.43.0.windows.1 Precedence: bulk X-Mailing-List: linux-acpi@vger.kernel.org List-Id: List-Subscribe: List-Unsubscribe: MIME-Version: 1.0 X-ClientProxiedBy: lhrpeml500003.china.huawei.com (7.191.162.67) To frapeml500007.china.huawei.com (7.182.85.172) From: Shiju Jose Previously known as "ras: scrub: introduce subsystem + CXL/ACPI-RAS2 drivers". Augmenting EDAC for controlling RAS features ============================================ The proposed expansion of EDAC for controlling RAS features and exposing features control attributes to userspace in sysfs. Some Examples: - Scrub control - Error Check Scrub (ECS) control - ACPI RAS2 features - Post Package Repair (PPR) control - Memory Sparing Repair control etc. High level design is illustrated in the following diagram. _______________________________________________ | Userspace - Rasdaemon | | ____________ | | | RAS CXL | _______________ | | | Err Handler|----->| | | | |____________| | RAS Dynamic | | | ____________ | Scrub, Memory | | | | RAS Memory |----->| Repair Control| | | | Err Handler| |_______________| | | |____________| | | |__________________________|____________________| | | _______________________________|______________________________ | Kernel EDAC based SubSystem | for RAS Features Control | | ______________________________|____________________________ | || EDAC Core Sysfs EDAC| Bus | | || __________________________|________ _ _____________ | | || |/sys/bus/edac/devices//scrubX/ | | EDAC Device || | || |/sys/bus/edac/devices//ecsX/ |<->| EDAC MC || | || |/sys/bus/edac/devices//repairX | | EDAC Sysfs || | || |____________________________________| |_____________|| | || | EDAC Bus | | || Get | Get | | || __________ Features | Features __________ | | || | |Descs _________|______ Descs| | | | || |EDAC Scrub|<-----| EDAC Device | | EDAC Mem | | | || |__________| | Driver- RAS |---->| Repair | | | || __________ | Feature Control| |__________| | | || | |<-----|________________| | | || |EDAC ECS | Register RAS | Features | | || |__________| | | | || ______________________|_________ | | ||_________|_____________|________________|__________________| | | _______|____ _____|_________ ____|_________ | | | | | CXL Mem Driver| | Client Driver| | | | ACPI RAS2 | | Sparing, PPR, | | Mem Repair | | | | Driver | | Scrub, ECS | | Features | | | |____________| |_______________| |______________| | | | | | | |________|______________|______________|_______________________| | | | _______|______________|______________|_______________________ | __|______________|_ ____________|____________ ____ | | | | | | | Platform HW and Firmware | | | |__________________________________________________| | |_____________________________________________________________| 1. EDAC RAS Features components - Create feature specific descriptors. for example, EDAC scrub, EDAC ECS, EDAC memory repair in the above diagram. 2. EDAC device driver for controlling RAS Features - Get feature's attr descriptors from EDAC RAS feature component and registers device's RAS features with EDAC bus and expose the feature's sysfs attributes under the sysfs EDAC bus. 3. RAS dynamic scrub controller - Userspace sample module added for scrub control in rasdaemon to issue scrubbing when excess number of memory errors are reported in a short span of time. The added EDAC feature specific components (e.g. EDAC scrub, EDAC ECS, EDAC memory repair etc) do callbacks to the parent driver (e.g. CXL driver, ACPI RAS driver etc) for the controls rather than just letting the caller deal with it because of the following reasons. 1. Enforces a common API across multiple implementations can do that via review, but that's not generally gone well in the long run for subsystems that have done it (several have later moved to callback and feature list based approaches). 2. Gives a path for 'intercepting' in the EDAC feature driver. An example for this is that we could intercept PPR repair calls and sanity check that the memory in question is offline before passing back to the underlying code. Sure we could rely on doing that via some additional calls from the parent driver, but the ABI will get messier. 3. (Speculative) we may get in kernel users of some features in the long run. More details of the common RAS features are described in the following sections. Memory Scrubbing ================ Increasing DRAM size and cost has made memory subsystem reliability an important concern. These modules are used where potentially corrupted data could cause expensive or fatal issues. Memory errors are one of the top hardware failures that cause server and workload crashes. Memory scrub is a feature where an ECC 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 could be scrubbed at a configurable rate to detect uncorrected memory errors and attempts to recover from detected memory errors providing the following benefits. - Proactively scrubbing memory DIMMs reduces the chance of a correctable error becoming uncorrectable. - Once detected, uncorrected errors caught in unallocated memory pages are isolated and prevented from being allocated to an application or the OS. - The probability of software/hardware products encountering memory errors is reduced. Some details of background can be found in Reference [5]. There are 2 types of memory scrubbing, 1. Background (patrol) scrubbing of the RAM whilst the RAM is otherwise idle. 2. On-demand scrubbing for a specific address range/region of memory. There are several types of interfaces to HW memory scrubbers identified such as ACPI NVDIMM ARS(Address Range Scrub), CXL memory device patrol scrub, CXL DDR5 ECS, ACPI RAS2 memory scrubbing. 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. Introduce generic memory EDAC scrub control which allows user to control underlying scrubbers in the system via generic sysfs scrub control interface. The common sysfs scrub control interface abstracts the control of an arbitrary scrubbing functionality to a common set of functions. Use case of common scrub control feature ======================================== 1. There are several types of interfaces to HW memory scrubbers identified such as ACPI NVDIMM ARS(Address Range Scrub), CXL memory device patrol scrub, CXL DDR5 ECS, ACPI RAS2 memory scrubbing features and software based memory scrubber(discussed in the community Reference [5]). Also some scrubbers support controlling (background) patrol scrubbing (ACPI RAS2, CXL) and/or on-demand scrubbing(ACPI RAS2, ACPI ARS). However the scrub controls varies between memory scrubbers. Thus there is a requirement for a standard generic sysfs scrub controls exposed to userspace for the seamless control of the HW/SW scrubbers in the system by admin/scripts/tools etc. 2. Scrub controls in user space allow the user to disable the scrubbing in case disabling of the background patrol scrubbing or changing the scrub rate are needed for other purposes such as performance-aware operations which requires the background operations to be turned off or reduced. 3. Allows to perform on-demand scrubbing for specific address range if supported by the scrubber. 4. User space tools controls scrub the memory DIMMs regularly at a configurable scrub rate using the sysfs scrub controls discussed help, - to detect uncorrectable memory errors early before user accessing memory, which helps to recover the detected memory errors. - reduces the chance of a correctable error becoming uncorrectable. 5. Policy control for hotplugged memory. There is not necessarily a system wide bios or similar in the loop to control the scrub settings on a CXL device that wasn't there at boot. What that setting should be is a policy decision as we are trading of reliability vs performance - hence it should be in control of userspace. As such, 'an' interface is needed. Seems more sensible to try and unify it with other similar interfaces than spin yet another one. The draft version of userspace code added in rasdaemon for dynamic scrub control, based on frequency of memory errors reported to userspace, tested for CXL device based patrol scrubbing feature and ACPI RAS2 based scrubbing feature. https://github.com/shijujose4/rasdaemon/tree/ras_feature_control ToDO: For memory repair features, such as PPR, memory sparing, rasdaemon collates records and decides to replace a row if there are lots of corrected errors, or a single uncorrected error or error record received with maintenance request flag set as in some CXL event records. Comparison of 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. ................................................................ . . . . . . . Clear UC . No . No . No . Supported . . error . . . . . . . . . . . ................................................................ . . . . . . . Translate . No . No . No . Supported . . *(1)SPA to . . . . . . *(2)DPA . . . . . ................................................................ *(1) - SPA - System Physical Address. See section 9.19.7.8 Function Index 5 - Translate SPA of ACPI spec r6.5. *(2) - DPA - Device Physical Address. See section 9.19.7.8 Function Index 5 - Translate SPA of ACPI spec r6.5. 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. 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. Note: However AmpereComputing has single entry repeated as they have centralized controls. - 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) ================================ 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. Note: Support for ARS is not added in this series because to reduce the line of code for review and could be added after initial code is merged. We'd like feedback on whether this is of interest to ARS community? Post Package Repair(PPR) ======================== PPR (Post Package Repair) maintenance operation requests the memory device to perform a repair operation on its media if supported. A memory device may support two types of PPR: Hard PPR (hPPR), for a permanent row repair, and Soft PPR (sPPR), for a temporary row repair. sPPR is much faster than hPPR, but the repair is lost with a power cycle. During the execution of a PPR maintenance operation, a memory device, may or may not retain data and may or may not be able to process memory requests correctly. sPPR maintenance operation may be executed at runtime, if data is retained and memory requests are correctly processed. hPPR maintenance operation may be executed only at boot because data would not be retained. Use cases of common PPR control feature ======================================= 1. The Soft PPR (sPPR) and Hard PPR (hPPR) share similar control interfaces, thus there is a requirement for a standard generic sysfs PPR controls exposed to userspace for the seamless control of the PPR features in the system by the admin/scripts/tools etc. 2. When a CXL device identifies a failure on a memory component, the device may inform the host about the need for a PPR maintenance operation by using an event record, where the maintenance needed flag is set. The event record specifies the DPA that should be repaired. Kernel reports the corresponding cxl general media or DRAM trace event to userspace. The userspace tool, for reg. rasdaemon initiate a PPR maintenance operation in response to a device request using the sysfs PPR control. 3. User space tools, for eg. rasdaemon, do request PPR on a memory region when uncorrected memory error or excess corrected memory errors reported on that memory. 4. Likely multiple instances of PPR present per memory device. Memory Sparing ============== Memory sparing is defined as a repair function that replaces a portion of memory with a portion of functional memory at that same DPA. User space tool, e.g. rasdaemon, may request the sparing operation for a given address for which the uncorrectable error is reported. In CXL, (CXL spec 3.1 section 8.2.9.7.1.4) subclasses for sparing operation vary in terms of the scope of the sparing being performed. The cacheline sparing subclass refers to a sparing action that can replace a full cacheline. Row sparing is provided as an alternative to PPR sparing functions and its scope is that of a single DDR row. Bank sparing allows an entire bank to be replaced. Rank sparing is defined as an operation in which an entire DDR rank is replaced. Series adds, 1. EDAC device driver extended for controlling RAS features, EDAC scrub driver, EDAC ECS driver, EDAC memory repair driver supports memory scrub control, ECS control, memory repair(PPR, sparing) control respectively. 2. Support for CXL feature mailbox commands, which is used by CXL device scrubbing and memory repair features. 3. CXL features driver supporting patrol scrub control (device and region based). 4. CXL features driver supporting ECS control feature. 5. ACPI RAS2 driver adds OS interface for RAS2 communication through PCC mailbox and extracts ACPI RAS2 feature table (RAS2) and create platform device for the RAS memory features, which binds to the memory ACPI RAS2 driver. 7. Memory ACPI RAS2 driver gets the PCC subspace for communicating with the ACPI compliant platform supports ACPI RAS2. Add callback functions and registers with EDAC device to support user to control the HW patrol scrubbers exposed to the kernel via the ACPI RAS2 table. 8. Support for CXL maintenance mailbox command, which is used by CXL device memory repair feature. 9. CXL features driver supporting PPR control feature. 9. CXL features driver supporting memory sparing control feature. 10. Note: There are other PPR, memory sparing drivers to come. Open Questions based on feedbacks from the community: 1. Leo: Standardize unit for scrub rate, for example ACPI RAS2 does not define unit for the scrub rate. RAS2 clarification needed. 2. Jonathan: Any need for discoverability of capability to scan different regions, such as global PA space to userspace. Left as future extension. 3. Jiaqi: - STOP_PATROL_SCRUBBER from RAS2 must be blocked and, must not be exposed to OS/userspace. Stopping patrol scrubber is unacceptable for platform where OEM has enabled patrol scrubber, because the patrol scrubber is a key part of logging and is repurposed for other RAS actions. If the OEM does not want to expose this control, they should lock it down so the interface is not exposed to the OS. These features are optional after all. - "Requested Address Range"/"Actual Address Range" (region to scrub) is a similarly bad thing to expose in RAS2. If the OEM does not want to expose this, they should lock it down so the interface is not exposed to the OS. These features are optional after all. 4. Borislav: - How the scrub control exposed to userspace will be used? POC added in rasdaemon with dynamic scrub control for CXL memory media errors and memory errors reported to userspace. https://github.com/shijujose4/rasdaemon/tree/scrub_control_6_june_2024 - Is the scrub interface is sufficient for the use cases? - Who is going to use scrub controls tools/admin/scripts? 1) Rasdaemon for dynamic control 2) Udev script for more static 'defaults' on hotplug etc. 5. PPR - For PPR, rasdaemon collates records and decides to replace a row if there are lots of corrected errors, or a single uncorrected error or error record received with maintenance request flag set as in CXL DRAM error record. - sPPR more or less startup only (so faking hPPR) or actually useful in a running system (if not the safe version that keeps everything running whilst replacement is ongoing) - Is future proofing for multiple PPR units useful given we've mashed together hPPR and sPPR for CXL. Implementation ============== 1. Linux kernel Latest version of kernel implementations of RAS features control is available in, https://github.com/shijujose4/linux.git Branch: edac-enhancement-ras-features_v13 2. QEMU emulation QEMU for CXL RAS features implementation is available in, https://gitlab.com/shiju.jose/qemu.git Branch: cxl-ras-features-2024-10-02 3. Userspace rasdaemon The draft version of userspace sample code for dynamic scrub control, based on frequency of memory errors reported to userspace, is added in rasdaemon and enabled, tested for CXL device based patrol scrubbing feature and ACPI RAS2 based scrubbing feature. https://github.com/shijujose4/rasdaemon/tree/ras_feature_control ToDO: For PPR, rasdaemon collates records and decides to replace a row if there are lots of corrected errors, or a single uncorrected error or error record received with maintenance request flag set as in CXL DRAM error record. References: 1. ACPI spec r6.5 section 5.2.21 ACPI RAS2. 2. ACPI spec r6.5 section 9.19.7.2 ARS. 3. CXL spec r3.1 8.2.9.9.11.1 Device patrol scrub control feature 4. CXL spec r3.1 8.2.9.9.11.2 DDR5 ECS feature 5. CXL spec r3.1 8.2.9.7.1.1 PPR Maintenance Operations 6. CXL spec r3.1 8.2.9.7.2.1 sPPR Feature Discovery and Configuration 7. CXL spec r3.1 8.2.9.7.2.2 hPPR Feature Discovery and Configuration 8. Background information about kernel support for memory scan, memory error detection and ACPI RASF. https://lore.kernel.org/all/20221103155029.2451105-1-jiaqiyan@google.com/ 9. Discussions on RASF: https://lore.kernel.org/lkml/20230915172818.761-1-shiju.jose@huawei.com/#r Changes ======= v12 -> v13: 1. Changes and Fixes for feedback from Boris - Function edac_dev_feat_init() merge with edac_dev_register() - Add macros in EDAC feature specific code for repeated code. - Correct spelling mistakes. - Removed feature specific code from the patch "EDAC: Add support for EDAC device features control" 2. Changes for feedbacks from Dave Jiang - Move fields num_features and entries to struct cxl_mailbox, in "cxl: Add Get Supported Features command for kernel usage" - Use series from https://lore.kernel.org/linux-cxl/20240905223711.1990186-1-dave.jiang@intel.com/ 3. Changes and Fixes for feedback from Ni Fan - In documentation scrub* to scrubX, ecs_fru* to ecs_fruX - Corrected some grammar mistakes in the patch headers. - Fixed an error print for min_scrub_cycle_hrs in the CXL patrol scrub code. - Improved an error print in the CXL ECS code. - bool -> tristate for config CXL_RAS_FEAT 4. Add support for CXL memory sparing feature. 5. Add common EDAC memory repair driver for controlling memory repair features, PPR, memory sparing etc. v11 -> v12: 1. Changes and Fixes for feedback from Boris mainly for patch "EDAC: Add support for EDAC device features control" and other generic comments. 2. Took CXL patches from Dave Jiang for "Add Get Supported Features command for kernel usage" and other related patches. Merged helper functions from this series to the above patch. Modifications of CXL code in this series due to refactoring of CXL mailbox in Dave's patches. 3. Modified EDAC scrub control code to support multiple scrub instances per device. v10 -> v11: 1. Feedback from Borislav: - Add generic EDAC code for control device features to /drivers/edac/edac_device.c. - Add common structure in edac for device feature's data. 2. Some more optimizations in generic EDAC code for control device features. 3. Changes for feedback from Fan for ACPI RAS2 memory driver. 4. Add support for control memory PPR (Post Package Repair) features in EDAC. 5. Add support for maintenance command in the CXL mailbox code, which is needed for support PPR features in CXL driver. 6. Add support for control memory PPR (Post Package Repair) features and do perform PPR maintenance operation in CXL driver. 7. Rename drivers/cxl/core/memscrub.c to drivers/cxl/core/memfeature.c v9 -> v10: 1. Feedback from Mauro Carvalho Chehab: - Changes suggested in EDAC RAS feature driver. use uppercase for enums, if else to switch-case, documentation for static scrub and ecs init functions etc. - Changes suggested in EDAC scrub. unit of scrub cycle hour to seconds. attribute node cycle_in_hours_available to min_cycle_duration and max_cycle_duration. attribute node cycle_in_hours to current_cycle_duration. Use base 0 for kstrtou64() and kstrtol() functions. etc. - Changes suggested in EDAC ECS. uppercase for enums add ABI documentation. etc 2. Feedback from Fan: - Changes suggested in EDAC RAS feature driver. use uppercase for enums, change if...else to switch-case. some optimization in edac_ras_dev_register() function add missing goto free_ctx - Changes suggested in the code for feature commands. - CXL driver scrub and ECS code use uppercase for enums, fix typo, use enum type for mode fix lonf lines etc. v8 -> v9: 1. Feedback from Borislav: - Add scrub control driver to the EDAC on feedback from Borislav. - Changed DEVICE_ATTR_..() static. - Changed the write permissions for scrub control sysfs files as root-only. 2. Feedback from Fan: - Optimized cxl_get_feature() function by using min() and removed feat_out_min_size. - Removed unreached return from cxl_set_feature() function. - Changed the term "rate" to "cycle_in_hours" in all the scrub control code. - Allow cxl_mem_probe() continue if cxl_mem_patrol_scrub_init() fail, with just a debug warning. 3. Feedback from Jonathan: - Removed patch __free() based cleanup function for acpi_put_table. and added fix in the acpi RAS2 driver. 4. Feedback from Dan Williams: - Allow cxl_mem_probe() continue if cxl_mem_patrol_scrub_init() fail, with just a debug warning. - Add support for CXL region based scrub control. 5. Feedback from Daniel Ferguson on RAS2 drivers: In the ACPI RAS2 driver, - Incorporated the changes given for clearing error reported. - Incorporated the changes given for check the Set RAS Capability status and return an appropriate error. In the RAS2 memory driver, - Added more checks for start/stop bg and on-demand scrubbing so that addr range in cache do not get cleared and restrict permitted operations during scrubbing. History for v1 to v8 is available here. https://lore.kernel.org/lkml/20240726160556.2079-1-shiju.jose@huawei.com/ Dave Jiang (4): cxl: move cxl headers to new include/cxl/ directory cxl: Move mailbox related bits to the same context cxl: Convert cxl_internal_send_cmd() to use 'struct cxl_mailbox' as input cxl: Add Get Supported Features command for kernel usage Jonathan Cameron (1): platform: Add __free() based cleanup function for platform_device_put Shiju Jose (13): EDAC: Add support for EDAC device features control EDAC: Add scrub control feature EDAC: Add ECS control feature cxl/mbox: Add GET_FEATURE mailbox command cxl/mbox: Add SET_FEATURE mailbox command cxl/memfeature: Add CXL memory device patrol scrub control feature cxl/memfeature: Add CXL memory device ECS control feature ACPI:RAS2: Add ACPI RAS2 driver ras: mem: Add memory ACPI RAS2 driver EDAC: Add memory repair control feature cxl/mbox: Add support for PERFORM_MAINTENANCE mailbox command cxl/memfeature: Add CXL memory device PPR control feature cxl/memfeature: Add CXL memory device memory sparing control feature Documentation/ABI/testing/sysfs-edac-ecs | 77 + .../ABI/testing/sysfs-edac-mem-repair | 152 ++ Documentation/ABI/testing/sysfs-edac-scrub | 69 + Documentation/edac/edac-scrub.rst | 115 ++ MAINTAINERS | 3 +- drivers/acpi/Kconfig | 10 + drivers/acpi/Makefile | 1 + drivers/acpi/apei/einj-cxl.c | 2 +- drivers/acpi/apei/ghes.c | 2 +- drivers/acpi/ras2.c | 391 ++++ drivers/cxl/Kconfig | 18 + drivers/cxl/core/Makefile | 1 + drivers/cxl/core/mbox.c | 420 ++++- drivers/cxl/core/memdev.c | 41 +- drivers/cxl/core/memfeature.c | 1656 +++++++++++++++++ drivers/cxl/core/port.c | 2 +- drivers/cxl/core/region.c | 6 + drivers/cxl/cxlmem.h | 156 +- drivers/cxl/mem.c | 4 + drivers/cxl/pci.c | 80 +- drivers/cxl/pmem.c | 10 +- drivers/cxl/security.c | 23 +- drivers/edac/Makefile | 1 + drivers/edac/ecs.c | 240 +++ drivers/edac/edac_device.c | 182 ++ drivers/edac/mem_repair.c | 317 ++++ drivers/edac/scrub.c | 223 +++ drivers/ras/Kconfig | 10 + drivers/ras/Makefile | 1 + drivers/ras/acpi_ras2.c | 449 +++++ include/acpi/ras2_acpi.h | 60 + include/{linux/einj-cxl.h => cxl/einj.h} | 0 include/{linux/cxl-event.h => cxl/event.h} | 0 include/cxl/mailbox.h | 32 + include/linux/edac.h | 184 ++ include/linux/platform_device.h | 1 + include/uapi/linux/cxl_mem.h | 1 + tools/testing/cxl/test/mem.c | 38 +- 38 files changed, 4858 insertions(+), 120 deletions(-) create mode 100644 Documentation/ABI/testing/sysfs-edac-ecs create mode 100644 Documentation/ABI/testing/sysfs-edac-mem-repair create mode 100644 Documentation/ABI/testing/sysfs-edac-scrub create mode 100644 Documentation/edac/edac-scrub.rst create mode 100755 drivers/acpi/ras2.c create mode 100644 drivers/cxl/core/memfeature.c create mode 100755 drivers/edac/ecs.c create mode 100755 drivers/edac/mem_repair.c create mode 100755 drivers/edac/scrub.c create mode 100644 drivers/ras/acpi_ras2.c create mode 100644 include/acpi/ras2_acpi.h rename include/{linux/einj-cxl.h => cxl/einj.h} (100%) rename include/{linux/cxl-event.h => cxl/event.h} (100%) create mode 100644 include/cxl/mailbox.h