arch/x86/kernel/cpu/mcheck/mce-severity.c - linux - Git at Google

 /*
  * MCE grading rules.
  * Copyright 2008, 2009 Intel Corporation.
  *
  * This program is free software; you can redistribute it and/or
  * modify it under the terms of the GNU General Public License
  * as published by the Free Software Foundation; version 2
  * of the License.
  *
  * Author: Andi Kleen
  */
 #include <linux/kernel.h>
 #include <linux/seq_file.h>
 #include <linux/init.h>
 #include <linux/debugfs.h>
 #include <asm/mce.h>
 #include <linux/uaccess.h>

 #include "mce-internal.h"

 /*
  * Grade an mce by severity. In general the most severe ones are processed
  * first. Since there are quite a lot of combinations test the bits in a
  * table-driven way. The rules are simply processed in order, first
  * match wins.
  *
  * Note this is only used for machine check exceptions, the corrected
  * errors use much simpler rules. The exceptions still check for the corrected
  * errors, but only to leave them alone for the CMCI handler (except for
  * panic situations)
  */

 enum context { IN_KERNEL = 1, IN_USER = 2, IN_KERNEL_RECOV = 3 };
 enum ser { SER_REQUIRED = 1, NO_SER = 2 };
 enum exception { EXCP_CONTEXT = 1, NO_EXCP = 2 };

 static struct severity {
 	u64 mask;
 	u64 result;
 	unsigned char sev;
 	unsigned char mcgmask;
 	unsigned char mcgres;
 	unsigned char ser;
 	unsigned char context;
 	unsigned char excp;
 	unsigned char covered;
 	char *msg;
 } severities[] = {
 #define MCESEV(s, m, c...) { .sev = MCE_ ## s ## _SEVERITY, .msg = m, ## c }
 #define  KERNEL		.context = IN_KERNEL
 #define  USER		.context = IN_USER
 #define  KERNEL_RECOV	.context = IN_KERNEL_RECOV
 #define  SER		.ser = SER_REQUIRED
 #define  NOSER		.ser = NO_SER
 #define  EXCP		.excp = EXCP_CONTEXT
 #define  NOEXCP		.excp = NO_EXCP
 #define  BITCLR(x)	.mask = x, .result = 0
 #define  BITSET(x)	.mask = x, .result = x
 #define  MCGMASK(x, y)	.mcgmask = x, .mcgres = y
 #define  MASK(x, y)	.mask = x, .result = y
 #define MCI_UC_S (MCI_STATUS_UC|MCI_STATUS_S)
 #define MCI_UC_AR (MCI_STATUS_UC|MCI_STATUS_AR)
 #define MCI_UC_SAR (MCI_STATUS_UC|MCI_STATUS_S|MCI_STATUS_AR)
 #define	MCI_ADDR (MCI_STATUS_ADDRV|MCI_STATUS_MISCV)

 	MCESEV(
 		NO, "Invalid",
 		BITCLR(MCI_STATUS_VAL)
 		),
 	MCESEV(
 		NO, "Not enabled",
 		EXCP, BITCLR(MCI_STATUS_EN)
 		),
 	MCESEV(
 		PANIC, "Processor context corrupt",
 		BITSET(MCI_STATUS_PCC)
 		),
 	/* When MCIP is not set something is very confused */
 	MCESEV(
 		PANIC, "MCIP not set in MCA handler",
 		EXCP, MCGMASK(MCG_STATUS_MCIP, 0)
 		),
 	/* Neither return not error IP -- no chance to recover -> PANIC */
 	MCESEV(
 		PANIC, "Neither restart nor error IP",
 		EXCP, MCGMASK(MCG_STATUS_RIPV|MCG_STATUS_EIPV, 0)
 		),
 	MCESEV(
 		PANIC, "In kernel and no restart IP",
 		EXCP, KERNEL, MCGMASK(MCG_STATUS_RIPV, 0)
 		),
 	MCESEV(
 		PANIC, "In kernel and no restart IP",
 		EXCP, KERNEL_RECOV, MCGMASK(MCG_STATUS_RIPV, 0)
 		),
 	MCESEV(
 		DEFERRED, "Deferred error",
 		NOSER, MASK(MCI_STATUS_UC|MCI_STATUS_DEFERRED|MCI_STATUS_POISON, MCI_STATUS_DEFERRED)
 		),
 	MCESEV(
 		KEEP, "Corrected error",
 		NOSER, BITCLR(MCI_STATUS_UC)
 		),

 	/*
 	 * known AO MCACODs reported via MCE or CMC:
 	 *
 	 * SRAO could be signaled either via a machine check exception or
 	 * CMCI with the corresponding bit S 1 or 0. So we don't need to
 	 * check bit S for SRAO.
 	 */
 	MCESEV(
 		AO, "Action optional: memory scrubbing error",
 		SER, MASK(MCI_STATUS_OVER|MCI_UC_AR|MCACOD_SCRUBMSK, MCI_STATUS_UC|MCACOD_SCRUB)
 		),
 	MCESEV(
 		AO, "Action optional: last level cache writeback error",
 		SER, MASK(MCI_STATUS_OVER|MCI_UC_AR|MCACOD, MCI_STATUS_UC|MCACOD_L3WB)
 		),

 	/* ignore OVER for UCNA */
 	MCESEV(
 		UCNA, "Uncorrected no action required",
 		SER, MASK(MCI_UC_SAR, MCI_STATUS_UC)
 		),
 	MCESEV(
 		PANIC, "Illegal combination (UCNA with AR=1)",
 		SER,
 		MASK(MCI_STATUS_OVER|MCI_UC_SAR, MCI_STATUS_UC|MCI_STATUS_AR)
 		),
 	MCESEV(
 		KEEP, "Non signalled machine check",
 		SER, BITCLR(MCI_STATUS_S)
 		),

 	MCESEV(
 		PANIC, "Action required with lost events",
 		SER, BITSET(MCI_STATUS_OVER|MCI_UC_SAR)
 		),

 	/* known AR MCACODs: */
 #ifdef	CONFIG_MEMORY_FAILURE
 	MCESEV(
 		KEEP, "Action required but unaffected thread is continuable",
 		SER, MASK(MCI_STATUS_OVER|MCI_UC_SAR|MCI_ADDR, MCI_UC_SAR|MCI_ADDR),
 		MCGMASK(MCG_STATUS_RIPV|MCG_STATUS_EIPV, MCG_STATUS_RIPV)
 		),
 	MCESEV(
 		AR, "Action required: data load in error recoverable area of kernel",
 		SER, MASK(MCI_STATUS_OVER|MCI_UC_SAR|MCI_ADDR|MCACOD, MCI_UC_SAR|MCI_ADDR|MCACOD_DATA),
 		KERNEL_RECOV
 		),
 	MCESEV(
 		AR, "Action required: data load error in a user process",
 		SER, MASK(MCI_STATUS_OVER|MCI_UC_SAR|MCI_ADDR|MCACOD, MCI_UC_SAR|MCI_ADDR|MCACOD_DATA),
 		USER
 		),
 	MCESEV(
 		AR, "Action required: instruction fetch error in a user process",
 		SER, MASK(MCI_STATUS_OVER|MCI_UC_SAR|MCI_ADDR|MCACOD, MCI_UC_SAR|MCI_ADDR|MCACOD_INSTR),
 		USER
 		),
 	MCESEV(
 		PANIC, "Data load in unrecoverable area of kernel",
 		SER, MASK(MCI_STATUS_OVER|MCI_UC_SAR|MCI_ADDR|MCACOD, MCI_UC_SAR|MCI_ADDR|MCACOD_DATA),
 		KERNEL
 		),
 #endif
 	MCESEV(
 		PANIC, "Action required: unknown MCACOD",
 		SER, MASK(MCI_STATUS_OVER|MCI_UC_SAR, MCI_UC_SAR)
 		),

 	MCESEV(
 		SOME, "Action optional: unknown MCACOD",
 		SER, MASK(MCI_STATUS_OVER|MCI_UC_SAR, MCI_UC_S)
 		),
 	MCESEV(
 		SOME, "Action optional with lost events",
 		SER, MASK(MCI_STATUS_OVER|MCI_UC_SAR, MCI_STATUS_OVER|MCI_UC_S)
 		),

 	MCESEV(
 		PANIC, "Overflowed uncorrected",
 		BITSET(MCI_STATUS_OVER|MCI_STATUS_UC)
 		),
 	MCESEV(
 		UC, "Uncorrected",
 		BITSET(MCI_STATUS_UC)
 		),
 	MCESEV(
 		SOME, "No match",
 		BITSET(0)
 		)	/* always matches. keep at end */
 };

 #define mc_recoverable(mcg) (((mcg) & (MCG_STATUS_RIPV|MCG_STATUS_EIPV)) == \
 				(MCG_STATUS_RIPV|MCG_STATUS_EIPV))

 /*
  * If mcgstatus indicated that ip/cs on the stack were
  * no good, then "m->cs" will be zero and we will have
  * to assume the worst case (IN_KERNEL) as we actually
  * have no idea what we were executing when the machine
  * check hit.
  * If we do have a good "m->cs" (or a faked one in the
  * case we were executing in VM86 mode) we can use it to
  * distinguish an exception taken in user from from one
  * taken in the kernel.
  */
 static int error_context(struct mce *m)
 {
 	if ((m->cs & 3) == 3)
 		return IN_USER;
 	if (mc_recoverable(m->mcgstatus) && ex_has_fault_handler(m->ip))
 		return IN_KERNEL_RECOV;
 	return IN_KERNEL;
 }

 static int mce_severity_amd_smca(struct mce *m, enum context err_ctx)
 {
 	u32 addr = MSR_AMD64_SMCA_MCx_CONFIG(m->bank);
 	u32 low, high;

 	/*
 	 * We need to look at the following bits:
 	 * - "succor" bit (data poisoning support), and
 	 * - TCC bit (Task Context Corrupt)
 	 * in MCi_STATUS to determine error severity.
 	 */
 	if (!mce_flags.succor)
 		return MCE_PANIC_SEVERITY;

 	if (rdmsr_safe(addr, &low, &high))
 		return MCE_PANIC_SEVERITY;

 	/* TCC (Task context corrupt). If set and if IN_KERNEL, panic. */
 	if ((low & MCI_CONFIG_MCAX) &&
 	    (m->status & MCI_STATUS_TCC) &&
 	    (err_ctx == IN_KERNEL))
 		return MCE_PANIC_SEVERITY;

 	 /* ...otherwise invoke hwpoison handler. */
 	return MCE_AR_SEVERITY;
 }

 /*
  * See AMD Error Scope Hierarchy table in a newer BKDG. For example
  * 49125_15h_Models_30h-3Fh_BKDG.pdf, section "RAS Features"
  */
 static int mce_severity_amd(struct mce *m, int tolerant, char **msg, bool is_excp)
 {
 	enum context ctx = error_context(m);

 	/* Processor Context Corrupt, no need to fumble too much, die! */
 	if (m->status & MCI_STATUS_PCC)
 		return MCE_PANIC_SEVERITY;

 	if (m->status & MCI_STATUS_UC) {

 		if (ctx == IN_KERNEL)
 			return MCE_PANIC_SEVERITY;

 		/*
 		 * On older systems where overflow_recov flag is not present, we
 		 * should simply panic if an error overflow occurs. If
 		 * overflow_recov flag is present and set, then software can try
 		 * to at least kill process to prolong system operation.
 		 */
 		if (mce_flags.overflow_recov) {
 			if (mce_flags.smca)
 				return mce_severity_amd_smca(m, ctx);

 			/* kill current process */
 			return MCE_AR_SEVERITY;
 		} else {
 			/* at least one error was not logged */
 			if (m->status & MCI_STATUS_OVER)
 				return MCE_PANIC_SEVERITY;
 		}

 		/*
 		 * For any other case, return MCE_UC_SEVERITY so that we log the
 		 * error and exit #MC handler.
 		 */
 		return MCE_UC_SEVERITY;
 	}

 	/*
 	 * deferred error: poll handler catches these and adds to mce_ring so
 	 * memory-failure can take recovery actions.
 	 */
 	if (m->status & MCI_STATUS_DEFERRED)
 		return MCE_DEFERRED_SEVERITY;

 	/*
 	 * corrected error: poll handler catches these and passes responsibility
 	 * of decoding the error to EDAC
 	 */
 	return MCE_KEEP_SEVERITY;
 }

 static int mce_severity_intel(struct mce *m, int tolerant, char **msg, bool is_excp)
 {
 	enum exception excp = (is_excp ? EXCP_CONTEXT : NO_EXCP);
 	enum context ctx = error_context(m);
 	struct severity *s;

 	for (s = severities;; s++) {
 		if ((m->status & s->mask) != s->result)
 			continue;
 		if ((m->mcgstatus & s->mcgmask) != s->mcgres)
 			continue;
 		if (s->ser == SER_REQUIRED && !mca_cfg.ser)
 			continue;
 		if (s->ser == NO_SER && mca_cfg.ser)
 			continue;
 		if (s->context && ctx != s->context)
 			continue;
 		if (s->excp && excp != s->excp)
 			continue;
 		if (msg)
 			*msg = s->msg;
 		s->covered = 1;
 		if (s->sev >= MCE_UC_SEVERITY && ctx == IN_KERNEL) {
 			if (tolerant < 1)
 				return MCE_PANIC_SEVERITY;
 		}
 		return s->sev;
 	}
 }

 /* Default to mce_severity_intel */
 int (*mce_severity)(struct mce *m, int tolerant, char **msg, bool is_excp) =
 		    mce_severity_intel;

 void __init mcheck_vendor_init_severity(void)
 {
 	if (boot_cpu_data.x86_vendor == X86_VENDOR_AMD)
 		mce_severity = mce_severity_amd;
 }

 #ifdef CONFIG_DEBUG_FS
 static void *s_start(struct seq_file *f, loff_t *pos)
 {
 	if (*pos >= ARRAY_SIZE(severities))
 		return NULL;
 	return &severities[*pos];
 }

 static void *s_next(struct seq_file *f, void *data, loff_t *pos)
 {
 	if (++(*pos) >= ARRAY_SIZE(severities))
 		return NULL;
 	return &severities[*pos];
 }

 static void s_stop(struct seq_file *f, void *data)
 {
 }

 static int s_show(struct seq_file *f, void *data)
 {
 	struct severity *ser = data;
 	seq_printf(f, "%d\t%s\n", ser->covered, ser->msg);
 	return 0;
 }

 static const struct seq_operations severities_seq_ops = {
 	.start	= s_start,
 	.next	= s_next,
 	.stop	= s_stop,
 	.show	= s_show,
 };

 static int severities_coverage_open(struct inode *inode, struct file *file)
 {
 	return seq_open(file, &severities_seq_ops);
 }

 static ssize_t severities_coverage_write(struct file *file,
 					 const char __user *ubuf,
 					 size_t count, loff_t *ppos)
 {
 	int i;
 	for (i = 0; i < ARRAY_SIZE(severities); i++)
 		severities[i].covered = 0;
 	return count;
 }

 static const struct file_operations severities_coverage_fops = {
 	.open		= severities_coverage_open,
 	.release	= seq_release,
 	.read		= seq_read,
 	.write		= severities_coverage_write,
 	.llseek		= seq_lseek,
 };

 static int __init severities_debugfs_init(void)
 {
 	struct dentry *dmce, *fsev;

 	dmce = mce_get_debugfs_dir();
 	if (!dmce)
 		goto err_out;

 	fsev = debugfs_create_file("severities-coverage", 0444, dmce, NULL,
 				   &severities_coverage_fops);
 	if (!fsev)
 		goto err_out;

 	return 0;

 err_out:
 	return -ENOMEM;
 }
 late_initcall(severities_debugfs_init);
 #endif /* CONFIG_DEBUG_FS */
	/*
	* MCE grading rules.
	* Copyright 2008, 2009 Intel Corporation.
	*
	* This program is free software; you can redistribute it and/or
	* modify it under the terms of the GNU General Public License
	* as published by the Free Software Foundation; version 2
	* of the License.
	*
	* Author: Andi Kleen
	*/
	#include <linux/kernel.h>
	#include <linux/seq_file.h>
	#include <linux/init.h>
	#include <linux/debugfs.h>
	#include <asm/mce.h>
	#include <linux/uaccess.h>

	#include "mce-internal.h"

	/*
	* Grade an mce by severity. In general the most severe ones are processed
	* first. Since there are quite a lot of combinations test the bits in a
	* table-driven way. The rules are simply processed in order, first
	* match wins.
	*
	* Note this is only used for machine check exceptions, the corrected
	* errors use much simpler rules. The exceptions still check for the corrected
	* errors, but only to leave them alone for the CMCI handler (except for
	* panic situations)
	*/

	enum context { IN_KERNEL = 1, IN_USER = 2, IN_KERNEL_RECOV = 3 };
	enum ser { SER_REQUIRED = 1, NO_SER = 2 };
	enum exception { EXCP_CONTEXT = 1, NO_EXCP = 2 };

	static struct severity {
	u64 mask;
	u64 result;
	unsigned char sev;
	unsigned char mcgmask;
	unsigned char mcgres;
	unsigned char ser;
	unsigned char context;
	unsigned char excp;
	unsigned char covered;
	char *msg;
	} severities[] = {
	#define MCESEV(s, m, c...) { .sev = MCE_ ## s ## _SEVERITY, .msg = m, ## c }
	#define KERNEL .context = IN_KERNEL
	#define USER .context = IN_USER
	#define KERNEL_RECOV .context = IN_KERNEL_RECOV
	#define SER .ser = SER_REQUIRED
	#define NOSER .ser = NO_SER
	#define EXCP .excp = EXCP_CONTEXT
	#define NOEXCP .excp = NO_EXCP
	#define BITCLR(x) .mask = x, .result = 0
	#define BITSET(x) .mask = x, .result = x
	#define MCGMASK(x, y) .mcgmask = x, .mcgres = y
	#define MASK(x, y) .mask = x, .result = y
	#define MCI_UC_S (MCI_STATUS_UC\|MCI_STATUS_S)
	#define MCI_UC_AR (MCI_STATUS_UC\|MCI_STATUS_AR)
	#define MCI_UC_SAR (MCI_STATUS_UC\|MCI_STATUS_S\|MCI_STATUS_AR)
	#define MCI_ADDR (MCI_STATUS_ADDRV\|MCI_STATUS_MISCV)

	MCESEV(
	NO, "Invalid",
	BITCLR(MCI_STATUS_VAL)
	),
	MCESEV(
	NO, "Not enabled",
	EXCP, BITCLR(MCI_STATUS_EN)
	),
	MCESEV(
	PANIC, "Processor context corrupt",
	BITSET(MCI_STATUS_PCC)
	),
	/* When MCIP is not set something is very confused */
	MCESEV(
	PANIC, "MCIP not set in MCA handler",
	EXCP, MCGMASK(MCG_STATUS_MCIP, 0)
	),
	/* Neither return not error IP -- no chance to recover -> PANIC */
	MCESEV(
	PANIC, "Neither restart nor error IP",
	EXCP, MCGMASK(MCG_STATUS_RIPV\|MCG_STATUS_EIPV, 0)
	),
	MCESEV(
	PANIC, "In kernel and no restart IP",
	EXCP, KERNEL, MCGMASK(MCG_STATUS_RIPV, 0)
	),
	MCESEV(
	PANIC, "In kernel and no restart IP",
	EXCP, KERNEL_RECOV, MCGMASK(MCG_STATUS_RIPV, 0)
	),
	MCESEV(
	DEFERRED, "Deferred error",
	NOSER, MASK(MCI_STATUS_UC\|MCI_STATUS_DEFERRED\|MCI_STATUS_POISON, MCI_STATUS_DEFERRED)
	),
	MCESEV(
	KEEP, "Corrected error",
	NOSER, BITCLR(MCI_STATUS_UC)
	),

	/*
	* known AO MCACODs reported via MCE or CMC:
	*
	* SRAO could be signaled either via a machine check exception or
	* CMCI with the corresponding bit S 1 or 0. So we don't need to
	* check bit S for SRAO.
	*/
	MCESEV(
	AO, "Action optional: memory scrubbing error",
	SER, MASK(MCI_STATUS_OVER\|MCI_UC_AR\|MCACOD_SCRUBMSK, MCI_STATUS_UC\|MCACOD_SCRUB)
	),
	MCESEV(
	AO, "Action optional: last level cache writeback error",
	SER, MASK(MCI_STATUS_OVER\|MCI_UC_AR\|MCACOD, MCI_STATUS_UC\|MCACOD_L3WB)
	),

	/* ignore OVER for UCNA */
	MCESEV(
	UCNA, "Uncorrected no action required",
	SER, MASK(MCI_UC_SAR, MCI_STATUS_UC)
	),
	MCESEV(
	PANIC, "Illegal combination (UCNA with AR=1)",
	SER,
	MASK(MCI_STATUS_OVER\|MCI_UC_SAR, MCI_STATUS_UC\|MCI_STATUS_AR)
	),
	MCESEV(
	KEEP, "Non signalled machine check",
	SER, BITCLR(MCI_STATUS_S)
	),

	MCESEV(
	PANIC, "Action required with lost events",
	SER, BITSET(MCI_STATUS_OVER\|MCI_UC_SAR)
	),

	/* known AR MCACODs: */
	#ifdef CONFIG_MEMORY_FAILURE
	MCESEV(
	KEEP, "Action required but unaffected thread is continuable",
	SER, MASK(MCI_STATUS_OVER\|MCI_UC_SAR\|MCI_ADDR, MCI_UC_SAR\|MCI_ADDR),
	MCGMASK(MCG_STATUS_RIPV\|MCG_STATUS_EIPV, MCG_STATUS_RIPV)
	),
	MCESEV(
	AR, "Action required: data load in error recoverable area of kernel",
	SER, MASK(MCI_STATUS_OVER\|MCI_UC_SAR\|MCI_ADDR\|MCACOD, MCI_UC_SAR\|MCI_ADDR\|MCACOD_DATA),
	KERNEL_RECOV
	),
	MCESEV(
	AR, "Action required: data load error in a user process",
	SER, MASK(MCI_STATUS_OVER\|MCI_UC_SAR\|MCI_ADDR\|MCACOD, MCI_UC_SAR\|MCI_ADDR\|MCACOD_DATA),
	USER
	),
	MCESEV(
	AR, "Action required: instruction fetch error in a user process",
	SER, MASK(MCI_STATUS_OVER\|MCI_UC_SAR\|MCI_ADDR\|MCACOD, MCI_UC_SAR\|MCI_ADDR\|MCACOD_INSTR),
	USER
	),
	MCESEV(
	PANIC, "Data load in unrecoverable area of kernel",
	SER, MASK(MCI_STATUS_OVER\|MCI_UC_SAR\|MCI_ADDR\|MCACOD, MCI_UC_SAR\|MCI_ADDR\|MCACOD_DATA),
	KERNEL
	),
	#endif
	MCESEV(
	PANIC, "Action required: unknown MCACOD",
	SER, MASK(MCI_STATUS_OVER\|MCI_UC_SAR, MCI_UC_SAR)
	),

	MCESEV(
	SOME, "Action optional: unknown MCACOD",
	SER, MASK(MCI_STATUS_OVER\|MCI_UC_SAR, MCI_UC_S)
	),
	MCESEV(
	SOME, "Action optional with lost events",
	SER, MASK(MCI_STATUS_OVER\|MCI_UC_SAR, MCI_STATUS_OVER\|MCI_UC_S)
	),

	MCESEV(
	PANIC, "Overflowed uncorrected",
	BITSET(MCI_STATUS_OVER\|MCI_STATUS_UC)
	),
	MCESEV(
	UC, "Uncorrected",
	BITSET(MCI_STATUS_UC)
	),
	MCESEV(
	SOME, "No match",
	BITSET(0)
	) /* always matches. keep at end */
	};

	#define mc_recoverable(mcg) (((mcg) & (MCG_STATUS_RIPV\|MCG_STATUS_EIPV)) == \
	(MCG_STATUS_RIPV\|MCG_STATUS_EIPV))

	/*
	* If mcgstatus indicated that ip/cs on the stack were
	* no good, then "m->cs" will be zero and we will have
	* to assume the worst case (IN_KERNEL) as we actually
	* have no idea what we were executing when the machine
	* check hit.
	* If we do have a good "m->cs" (or a faked one in the
	* case we were executing in VM86 mode) we can use it to
	* distinguish an exception taken in user from from one
	* taken in the kernel.
	*/
	static int error_context(struct mce *m)
	{
	if ((m->cs & 3) == 3)
	return IN_USER;
	if (mc_recoverable(m->mcgstatus) && ex_has_fault_handler(m->ip))
	return IN_KERNEL_RECOV;
	return IN_KERNEL;
	}

	static int mce_severity_amd_smca(struct mce *m, enum context err_ctx)
	{
	u32 addr = MSR_AMD64_SMCA_MCx_CONFIG(m->bank);
	u32 low, high;

	/*
	* We need to look at the following bits:
	* - "succor" bit (data poisoning support), and
	* - TCC bit (Task Context Corrupt)
	* in MCi_STATUS to determine error severity.
	*/
	if (!mce_flags.succor)
	return MCE_PANIC_SEVERITY;

	if (rdmsr_safe(addr, &low, &high))
	return MCE_PANIC_SEVERITY;

	/* TCC (Task context corrupt). If set and if IN_KERNEL, panic. */
	if ((low & MCI_CONFIG_MCAX) &&
	(m->status & MCI_STATUS_TCC) &&
	(err_ctx == IN_KERNEL))
	return MCE_PANIC_SEVERITY;

	/* ...otherwise invoke hwpoison handler. */
	return MCE_AR_SEVERITY;
	}

	/*
	* See AMD Error Scope Hierarchy table in a newer BKDG. For example
	* 49125_15h_Models_30h-3Fh_BKDG.pdf, section "RAS Features"
	*/
	static int mce_severity_amd(struct mce m, int tolerant, char *msg, bool is_excp)
	{
	enum context ctx = error_context(m);

	/* Processor Context Corrupt, no need to fumble too much, die! */
	if (m->status & MCI_STATUS_PCC)
	return MCE_PANIC_SEVERITY;

	if (m->status & MCI_STATUS_UC) {

	if (ctx == IN_KERNEL)
	return MCE_PANIC_SEVERITY;

	/*
	* On older systems where overflow_recov flag is not present, we
	* should simply panic if an error overflow occurs. If
	* overflow_recov flag is present and set, then software can try
	* to at least kill process to prolong system operation.
	*/
	if (mce_flags.overflow_recov) {
	if (mce_flags.smca)
	return mce_severity_amd_smca(m, ctx);

	/* kill current process */
	return MCE_AR_SEVERITY;
	} else {
	/* at least one error was not logged */
	if (m->status & MCI_STATUS_OVER)
	return MCE_PANIC_SEVERITY;
	}

	/*
	* For any other case, return MCE_UC_SEVERITY so that we log the
	* error and exit #MC handler.
	*/
	return MCE_UC_SEVERITY;
	}

	/*
	* deferred error: poll handler catches these and adds to mce_ring so
	* memory-failure can take recovery actions.
	*/
	if (m->status & MCI_STATUS_DEFERRED)
	return MCE_DEFERRED_SEVERITY;

	/*
	* corrected error: poll handler catches these and passes responsibility
	* of decoding the error to EDAC
	*/
	return MCE_KEEP_SEVERITY;
	}

	static int mce_severity_intel(struct mce m, int tolerant, char *msg, bool is_excp)
	{
	enum exception excp = (is_excp ? EXCP_CONTEXT : NO_EXCP);
	enum context ctx = error_context(m);
	struct severity *s;

	for (s = severities;; s++) {
	if ((m->status & s->mask) != s->result)
	continue;
	if ((m->mcgstatus & s->mcgmask) != s->mcgres)
	continue;
	if (s->ser == SER_REQUIRED && !mca_cfg.ser)
	continue;
	if (s->ser == NO_SER && mca_cfg.ser)
	continue;
	if (s->context && ctx != s->context)
	continue;
	if (s->excp && excp != s->excp)
	continue;
	if (msg)
	*msg = s->msg;
	s->covered = 1;
	if (s->sev >= MCE_UC_SEVERITY && ctx == IN_KERNEL) {
	if (tolerant < 1)
	return MCE_PANIC_SEVERITY;
	}
	return s->sev;
	}
	}

	/* Default to mce_severity_intel */
	int (mce_severity)(struct mce m, int tolerant, char **msg, bool is_excp) =
	mce_severity_intel;

	void __init mcheck_vendor_init_severity(void)
	{
	if (boot_cpu_data.x86_vendor == X86_VENDOR_AMD)
	mce_severity = mce_severity_amd;
	}

	#ifdef CONFIG_DEBUG_FS
	static void s_start(struct seq_file f, loff_t *pos)
	{
	if (*pos >= ARRAY_SIZE(severities))
	return NULL;
	return &severities[*pos];
	}

	static void s_next(struct seq_file f, void data, loff_t pos)
	{
	if (++(*pos) >= ARRAY_SIZE(severities))
	return NULL;
	return &severities[*pos];
	}

	static void s_stop(struct seq_file f, void data)
	{
	}

	static int s_show(struct seq_file f, void data)
	{
	struct severity *ser = data;
	seq_printf(f, "%d\t%s\n", ser->covered, ser->msg);
	return 0;
	}

	static const struct seq_operations severities_seq_ops = {
	.start = s_start,
	.next = s_next,
	.stop = s_stop,
	.show = s_show,
	};

	static int severities_coverage_open(struct inode inode, struct file file)
	{
	return seq_open(file, &severities_seq_ops);
	}

	static ssize_t severities_coverage_write(struct file *file,
	const char __user *ubuf,
	size_t count, loff_t *ppos)
	{
	int i;
	for (i = 0; i < ARRAY_SIZE(severities); i++)
	severities[i].covered = 0;
	return count;
	}

	static const struct file_operations severities_coverage_fops = {
	.open = severities_coverage_open,
	.release = seq_release,
	.read = seq_read,
	.write = severities_coverage_write,
	.llseek = seq_lseek,
	};

	static int __init severities_debugfs_init(void)
	{
	struct dentry dmce, fsev;

	dmce = mce_get_debugfs_dir();
	if (!dmce)
	goto err_out;

	fsev = debugfs_create_file("severities-coverage", 0444, dmce, NULL,
	&severities_coverage_fops);
	if (!fsev)
	goto err_out;

	return 0;

	err_out:
	return -ENOMEM;
	}
	late_initcall(severities_debugfs_init);
	#endif /* CONFIG_DEBUG_FS */