xref: /illumos-gate/usr/src/cmd/fm/eversholt/files/i386/i86pc/amd64.esc (revision 355b4669e025ff377602b6fc7caaf30dbc218371)

/*
 * CDDL HEADER START
 *
 * The contents of this file are subject to the terms of the
 * Common Development and Distribution License (the "License").
 * You may not use this file except in compliance with the License.
 *
 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
 * or http://www.opensolaris.org/os/licensing.
 * See the License for the specific language governing permissions
 * and limitations under the License.
 *
 * When distributing Covered Code, include this CDDL HEADER in each
 * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
 * If applicable, add the following below this CDDL HEADER, with the
 * fields enclosed by brackets "[]" replaced with your own identifying
 * information: Portions Copyright [yyyy] [name of copyright owner]
 *
 * CDDL HEADER END
 */

/*
 * Copyright 2006 Sun Microsystems, Inc.  All rights reserved.
 * Use is subject to license terms.
 */

#pragma ident	"%Z%%M%	%I%	%E% SMI"

#pragma dictionary "AMD"

/*
 * Eversholt rules for the AMD Opteron CPU/Memory
 */

fru dimm;
asru dimm;

fru chip;
asru chip/cpu;


/*								#MEM#
 * GET_ADDR relies on the fact that variables have global scope across an FME.
 * Thus for each FME the assignment only occurs for the first invocation
 * but the comparison happens on each. Thus if the new address matches the
 * address of an existing open FME, then we return true running in the context
 * of that FME. If the new address doesn't match the address of any existing
 * open FME, then we return true in the context of a newly opened FME.
 */
#define GET_ADDR (defined($addr) ? ($addr == payloadprop("addr")) :	\
	($addr = payloadprop("addr")))

#define	GET_OFFSET ($offset = payloadprop("resource[0].hc-specific.offset"))

/*
 * SET_ADDR is used to set a payload value in the fault that we diagnose
 * for page faults, to record the physical address of the faulting page.
 */
#define	SET_ADDR (setpayloadprop("asru-physaddr", $addr))

#define	SET_OFFSET (setpayloadprop("asru-offset", $offset))

/*
 * RESOURCE_EXISTS is true if a pair with name "resource" exists in the
 * payload - regardless of type (e.g., nvlist or nvlist array) or value.
 */
#define	RESOURCE_EXISTS	(payloadprop_defined("resource"))

/*
 * CONTAINS_DIMM is true if the "resource" nvlist array (as used in memory
 * ereports) exists and one if its members matches the path for the
 * dimm node.  Our memory propogation are of the form "foo@dimm -> blah@cpu"
 * since cpus detect memory errors;  in eversholt such a propogation, where
 * the lhs path and rhs path do not match, expands to the cross-product of
 * all dimms and cpus in the system.  We use CONTAINS_DIMM to constrain
 * the propogation such that it only happens if the payload resource
 * matches the dimm.
 */
#define	CONTAINS_DIMM (payloadprop_contains("resource", asru(dimm)))

/*
 * The following will tell us whether a syndrome that is known to be
 * correctable (from a mem_ecc1) is single-bit or multi-bit.  For a
 * correctable ChipKill syndrome the number of bits set in the lowest
 * nibble indicates how many bit were in error.
 */

#define	CBITMASK(synd) ((synd) & 0xf)

#define	CKSINGLE(synd)							\
	((synd) == 0 ||							\
	(CBITMASK(synd) == 0x1 || CBITMASK(synd) == 0x2 ||		\
	CBITMASK(synd) == 0x4 || CBITMASK(synd) == 0x8))

#define	SINGLE_BIT_CE							\
	(payloadprop("syndrome-type") == "E" ||				\
	(payloadprop("syndrome-type") == "C" &&				\
	CKSINGLE(payloadprop("syndrome"))))

#define	MULTI_BIT_CE							\
	(payloadprop("syndrome-type") == "C" &&				\
	!CKSINGLE(payloadprop("syndrome")))

/*
 * A single bit fault in a memory dimm can cause:
 *
 *  - mem_ce : reported by nb for an access from a remote cpu
 *
 * Single-bit errors are fed into a per-DIMM SERD engine; if a SERD engine
 * trips we diagnose a fault.memory.page so that the response agent can
 * retire the page that caused the trip.  If the total number of pages
 * faulted in this way on a single DIMM exceeds a threshold we will
 * diagnose a fault.memory.dimm_sb against the DIMM.
 *
 * Multibit ChipKill-correctable errors produce an immediate page fault.
 * This is achieved through SERD engines using N=0 so the facility is there
 * to be a little more tolerant of these errors in future.
 *
 * Uncorrectable errors produce an immediate page fault and corresponding
 * fault.memory.dimm_ue.
 *
 * Page faults are essentially internal - action is only required when
 * they are accompanied by a dimm fault.  As such we include message=0
 * on DIMM faults.
 */

event ereport.cpu.amd.nb.mem_ce@cpu;

/*
 * If the address is not valid then no resource member will be included
 * in a nb.mem_ce or nb.mem_ue ereport.  These cases should be rare.
 * We will discard such ereports.  An alternative may be to SERD them
 * on a per MC basis and trip if we see too many such events.
 */

event upset.memory.discard@cpu;

/*								#PAGE#
 * Page faults of all types diagnose to a single fault class and are
 * counted with a stat.
 *
 * Single-bit errors are diagnosed as upsets and feed into per-DIMM
 * SERD engines which diagnose fault.memory.page if they trip.
 */

#define PAGE_FIT		1
#define PAGE_SB_COUNT		2
#define PAGE_SB_TIME		72h
#define	PAGE_CK_COUNT		0
#define	PAGE_CK_TIME		1h

engine stat.page_fault@dimm;
event fault.memory.page@dimm, FITrate=PAGE_FIT,
    ASRU=dimm, message=0, count=stat.page_fault@dimm,
    action=confcall("rewrite-ASRU");
event error.memory.page_sb@dimm;
event error.memory.page_ck@dimm;
event error.memory.page_ue@dimm;

prop fault.memory.page@dimm (1)->
    error.memory.page_sb@dimm,
    error.memory.page_ck@dimm,
    error.memory.page_ue@dimm;

event ereport.memory.page_sb_trip@dimm;
engine serd.memory.page_sb@dimm, N=PAGE_SB_COUNT, T=PAGE_SB_TIME,
    method=persistent, trip=ereport.memory.page_sb_trip@dimm;
event upset.memory.page_sb@dimm, engine=serd.memory.page_sb@dimm;

event ereport.memory.page_ck_trip@dimm;
engine serd.memory.page_ck@dimm, N=PAGE_CK_COUNT, T=PAGE_CK_TIME,
    method=persistent, trip=ereport.memory.page_ck_trip@dimm;
event upset.memory.page_ck@dimm, engine=serd.memory.page_ck@dimm;

prop upset.memory.page_sb@dimm (0)->
    ereport.cpu.amd.nb.mem_ce@cpu { CONTAINS_DIMM && SINGLE_BIT_CE };

prop upset.memory.page_ck@dimm (0)->
    ereport.cpu.amd.nb.mem_ce@cpu { CONTAINS_DIMM && MULTI_BIT_CE };

prop error.memory.page_sb@dimm (1)->
    ereport.memory.page_sb_trip@dimm;

prop error.memory.page_ck@dimm (1)->
    ereport.memory.page_ck_trip@dimm;

prop fault.memory.page@dimm { SET_ADDR && SET_OFFSET } (0)->
    ereport.cpu.amd.nb.mem_ce@cpu { CONTAINS_DIMM && GET_ADDR && GET_OFFSET };

prop upset.memory.discard@cpu (1)->
    ereport.cpu.amd.nb.mem_ce@cpu { !RESOURCE_EXISTS };

/*								#DIMM_SB#
 * Single-bit DIMM faults are diagnosed when the number of page faults
 * (of all types since they all are counted in a single per-DIMM stat engine)
 * reaches a threshold.  Since our tolerance of ChipKill and UE faults
 * is much lower than that for single-bit errors the threshold will only be
 * reached for repeated single-bit page faults.  We do not stop diagnosing
 * further single-bit page faults once we have declared a single-bit DIMM
 * fault - we continue diagnosing them and response agents can continue to
 * retire those pages up to the system-imposed retirement limit.
 *
 * We maintain a parallel SERD engine to the page_sb engine which trips
 * in unison, but on trip it generates a distinct ereport which we
 * diagnose to a dimm_sb fault if the threshold has been reached, or
 * to a throwaway upset if not.
 */

#define DIMM_SB_FIT		2000
#define DIMM_SB_THRESH		128

event fault.memory.dimm_sb@dimm, FITrate=DIMM_SB_FIT, FRU=dimm, ASRU=dimm,
    action=confcall("rewrite-ASRU");

event ereport.memory.dimm_sb_trip@dimm;
event upset.memory.discard@dimm;
engine serd.memory.dimm_sb@dimm, N=PAGE_SB_COUNT, T=PAGE_SB_TIME,
    method=persistent, trip=ereport.memory.dimm_sb_trip@dimm;
event upset.memory.dimm_sb@dimm, engine=serd.memory.dimm_sb@dimm;

prop upset.memory.dimm_sb@dimm (0)->
    ereport.cpu.amd.nb.mem_ce@cpu { CONTAINS_DIMM };	/* sb and ck */

prop upset.memory.discard@dimm (1)->
    ereport.memory.dimm_sb_trip@dimm;

prop fault.memory.dimm_sb@dimm (0)->
    ereport.memory.dimm_sb_trip@dimm {
	count(stat.page_fault@dimm) >= DIMM_SB_THRESH };

/*								#DIMM_CK#
 * ChipKill-correctable multi-bit errors produce immediate page faults.
 * If the fault is indeed isolated to just a few cells then we have contained
 * the error;  if not, say if the SDRAM device is failing, then we will hit a
 * number of other similar errors in a short space of time.  Thus we will
 * SERD these in diagnosing a fault.memory.dimm_ck and not simply fault
 * the DIMM at the first instance.
 */

#define DIMM_CK_FIT		4000
#define	DIMM_CK_COUNT		2
#define	DIMM_CK_TIME		72h

event fault.memory.dimm_ck@dimm, FITrate=DIMM_CK_FIT, FRU=dimm, ASRU=dimm,
    action=confcall("rewrite-ASRU");

event ereport.memory.dimm_ck_trip@dimm;
engine serd.memory.dimm_ck@dimm, N=DIMM_CK_COUNT, T=DIMM_CK_TIME,
    method=persistent, trip=ereport.memory.dimm_ck_trip@dimm;
event upset.memory.dimm_ck@dimm, engine=serd.memory.dimm_ck@dimm;

prop upset.memory.dimm_ck@dimm (0)->
    ereport.cpu.amd.nb.mem_ce@cpu { CONTAINS_DIMM && MULTI_BIT_CE };

prop fault.memory.dimm_ck@dimm (1)->
    ereport.memory.dimm_ck_trip@dimm;

prop fault.memory.page@dimm { SET_ADDR && SET_OFFSET } (0)->
    ereport.cpu.amd.nb.mem_ce@cpu { CONTAINS_DIMM && MULTI_BIT_CE &&
    GET_ADDR && GET_OFFSET };

/* 								#DIMM_UE#
 * A multi-bit fault in a memory dimm can cause:
 *
 *  - ue    : reported by nb for an access from a remote cpu
 *
 * Note we use a SERD engine here simply as a way of ensuring that we get
 * both dimm and page faults reported
 */

#define DIMM_UE_FIT		6000

event ereport.cpu.amd.nb.mem_ue@cpu;
event ereport.memory.page_ue_trip@dimm;
event ereport.memory.dimm_ue_trip@dimm;
event fault.memory.dimm_ue@dimm, FITrate=DIMM_UE_FIT, FRU=dimm, ASRU=dimm,
    action=confcall("rewrite-ASRU");
event upset.memory.page_ue@dimm, engine=serd.memory.page_ue@dimm;
event upset.memory.dimm_ue@dimm, engine=serd.memory.dimm_ue@dimm;

engine serd.memory.dimm_ue@dimm, N=0, T=1h,
    method=persistent, trip=ereport.memory.dimm_ue_trip@dimm;

engine serd.memory.page_ue@dimm, N=0, T=1h,
    method=persistent, trip=ereport.memory.page_ue_trip@dimm;

prop upset.memory.page_ue@dimm (0)->
    ereport.cpu.amd.nb.mem_ue@cpu { CONTAINS_DIMM };

prop upset.memory.dimm_ue@dimm (0)->
    ereport.cpu.amd.nb.mem_ue@cpu { CONTAINS_DIMM };

prop error.memory.page_ue@dimm (1)->
    ereport.memory.page_ue_trip@dimm;

prop fault.memory.page@dimm { SET_ADDR && SET_OFFSET } (0)->
    ereport.cpu.amd.nb.mem_ue@cpu { CONTAINS_DIMM && GET_ADDR & GET_OFFSET };

prop fault.memory.dimm_ue@dimm (1)->
    ereport.memory.dimm_ue_trip@dimm;

prop upset.memory.discard@cpu (1)->
    ereport.cpu.amd.nb.mem_ce@cpu { !RESOURCE_EXISTS };

/*								#L2D#
 * l2 cache data errors.
 */

#define L2CACHEDATA_FIT		1000
#define L2CACHEDATA_SB_COUNT	3
#define L2CACHEDATA_SB_TIME	12h

event fault.cpu.amd.l2cachedata@chip/cpu, FITrate=L2CACHEDATA_FIT,
	FRU=chip, ASRU=chip/cpu;
event error.cpu.amd.l2cachedata_sb@chip/cpu;
event error.cpu.amd.l2cachedata_mb@chip/cpu;

prop fault.cpu.amd.l2cachedata@chip/cpu (1)->
    error.cpu.amd.l2cachedata_sb@chip/cpu,
    error.cpu.amd.l2cachedata_mb@chip/cpu;

/* 								#L2D_SINGLE#
 * A single bit data array fault in an l2 cache can cause:
 *
 *  - inf_l2_ecc1 : reported by ic on this cpu
 *  - inf_l2_ecc1 : reported by dc on this cpu
 *  - l2d_ecc1 : reported by bu on copyback or on snoop from another cpu
 *
 * Single-bit errors are diagnosed to cache upsets.  SERD engines are used
 * to count upsets resulting from CEs.
 */

event ereport.cpu.amd.ic.inf_l2_ecc1@chip/cpu{within(5s)};
event ereport.cpu.amd.dc.inf_l2_ecc1@chip/cpu{within(5s)};
event ereport.cpu.amd.bu.l2d_ecc1@chip/cpu{within(5s)};
event ereport.cpu.amd.l2d_sb_trip@chip/cpu;

engine serd.cpu.amd.l2d_sb@chip/cpu,
    N=L2CACHEDATA_SB_COUNT, T=L2CACHEDATA_SB_TIME, method=persistent,
    trip=ereport.cpu.amd.l2d_sb_trip@chip/cpu;

event upset.cpu.amd.l2d_sb@chip/cpu,
	engine=serd.cpu.amd.l2d_sb@chip/cpu;

prop upset.cpu.amd.l2d_sb@chip/cpu (1)->
    ereport.cpu.amd.ic.inf_l2_ecc1@chip/cpu,
    ereport.cpu.amd.dc.inf_l2_ecc1@chip/cpu,
    ereport.cpu.amd.bu.l2d_ecc1@chip/cpu;

prop error.cpu.amd.l2cachedata_sb@chip/cpu (1)->
    ereport.cpu.amd.l2d_sb_trip@chip/cpu;

prop fault.cpu.amd.l2cachedata@chip/cpu (0)->
    ereport.cpu.amd.ic.inf_l2_ecc1@chip/cpu,
    ereport.cpu.amd.dc.inf_l2_ecc1@chip/cpu,
    ereport.cpu.amd.bu.l2d_ecc1@chip/cpu;

/* 								#L2D_MULTI#
 * A multi-bit data array fault in an l2 cache can cause:
 *
 *  - inf_l2_eccm : reported by ic on this cpu
 *  - inf_l2_eccm : reported by dc on this cpu
 *  - l2d_eccm : reported by bu on copyback or on snoop from another cpu
 */

event ereport.cpu.amd.ic.inf_l2_eccm@chip/cpu;
event ereport.cpu.amd.dc.inf_l2_eccm@chip/cpu;
event ereport.cpu.amd.bu.l2d_eccm@chip/cpu;

prop error.cpu.amd.l2cachedata_mb@chip/cpu (1)->
    ereport.cpu.amd.ic.inf_l2_eccm@chip/cpu,
    ereport.cpu.amd.dc.inf_l2_eccm@chip/cpu,
    ereport.cpu.amd.bu.l2d_eccm@chip/cpu;

prop fault.cpu.amd.l2cachedata@chip/cpu (0)->
    ereport.cpu.amd.ic.inf_l2_eccm@chip/cpu,
    ereport.cpu.amd.dc.inf_l2_eccm@chip/cpu,
    ereport.cpu.amd.bu.l2d_eccm@chip/cpu;

/*								#L2T#
 * l2 cache main tag errors
 */

#define L2CACHETAG_FIT		1000
#define L2CACHETAG_SB_COUNT	3
#define L2CACHETAG_SB_TIME	12h

event fault.cpu.amd.l2cachetag@chip/cpu, FITrate=L2CACHETAG_FIT,
	FRU=chip, ASRU=chip/cpu;
event error.cpu.amd.l2cachetag_sb@chip/cpu;
event error.cpu.amd.l2cachetag_mb@chip/cpu;

prop fault.cpu.amd.l2cachetag@chip/cpu (1)->
    error.cpu.amd.l2cachetag_sb@chip/cpu,
    error.cpu.amd.l2cachetag_mb@chip/cpu;

/* 								#L2T_SINGLE#
 * A single bit tag array fault in an l2 cache can cause:
 *
 *  - l2t_ecc1 : reported by bu on this cpu when detected during snoop
 *  - l2t_par : reported by bu on this cpu when detected other than during snoop
 *
 * Note that the bu.l2t_par ereport could be due to a single bit or multi bit
 * event. If the l2t_sb_trip has already triggered it will be treated as another
 * ce, otherwise it will be treated as a ue event.
 */

event ereport.cpu.amd.bu.l2t_ecc1@chip/cpu{within(5s)};
event ereport.cpu.amd.bu.l2t_par@chip/cpu;
event ereport.cpu.amd.l2t_sb_trip@chip/cpu;

engine serd.cpu.amd.l2t_sb@chip/cpu,
    N=L2CACHETAG_SB_COUNT, T=L2CACHETAG_SB_TIME, method=persistent,
    trip=ereport.cpu.amd.l2t_sb_trip@chip/cpu;

event upset.cpu.amd.l2t_sb@chip/cpu,
	engine=serd.cpu.amd.l2t_sb@chip/cpu;

prop upset.cpu.amd.l2t_sb@chip/cpu (1)->
    ereport.cpu.amd.bu.l2t_ecc1@chip/cpu,
    ereport.cpu.amd.bu.l2t_par@chip/cpu;

prop error.cpu.amd.l2cachetag_sb@chip/cpu (1)->
    ereport.cpu.amd.l2t_sb_trip@chip/cpu;

prop fault.cpu.amd.l2cachetag@chip/cpu (0)->
    ereport.cpu.amd.bu.l2t_ecc1@chip/cpu,
    ereport.cpu.amd.bu.l2t_par@chip/cpu;

/* 								#L2T_MULTI#
 * A multi-bit tag array fault in an l2 cache can cause:
 *
 *  - l2t_eccm : reported by bu on this cpu when detected during snoop
 *  - l2t_par : reported by bu on this cpu when detected other than during snoop
 */

event ereport.cpu.amd.bu.l2t_eccm@chip/cpu;

prop error.cpu.amd.l2cachetag_mb@chip/cpu (1)->
    ereport.cpu.amd.bu.l2t_eccm@chip/cpu,
    ereport.cpu.amd.bu.l2t_par@chip/cpu;

prop fault.cpu.amd.l2cachetag@chip/cpu (0)->
    ereport.cpu.amd.bu.l2t_eccm@chip/cpu,
    ereport.cpu.amd.bu.l2t_par@chip/cpu;

/* 								#ICD_PAR#
 * A data array parity fault in an I cache can cause:
 *
 *  - data_par : reported by ic on this cpu
 */

#define ICACHEDATA_FIT		1000
#define ICACHEDATA_SB_COUNT	2
#define ICACHEDATA_SB_TIME	168h

event ereport.cpu.amd.ic.data_par@chip/cpu{within(5s)};
event ereport.cpu.amd.ic_dp_trip@chip/cpu;

event fault.cpu.amd.icachedata@chip/cpu, FITrate=ICACHEDATA_FIT,
	FRU=chip, ASRU=chip/cpu;

engine serd.cpu.amd.icachedata@chip/cpu,
    N=ICACHEDATA_SB_COUNT, T=ICACHEDATA_SB_TIME, method=persistent,
    trip=ereport.cpu.amd.ic_dp_trip@chip/cpu;

event upset.cpu.amd.icachedata@chip/cpu,
	engine=serd.cpu.amd.icachedata@chip/cpu;

prop upset.cpu.amd.icachedata@chip/cpu (1)->
    ereport.cpu.amd.ic.data_par@chip/cpu;

prop fault.cpu.amd.icachedata@chip/cpu (1)->
    ereport.cpu.amd.ic_dp_trip@chip/cpu;

prop fault.cpu.amd.icachedata@chip/cpu (0)->
    ereport.cpu.amd.ic.data_par@chip/cpu;

/* 								#ICT_PAR#
 * A tag array parity fault in an I cache can cause:
 *
 *  - tag_par : reported by ic on this cpu
 */

#define ICACHETAG_FIT		1000
#define ICACHETAG_SB_COUNT	2
#define ICACHETAG_SB_TIME	168h

event ereport.cpu.amd.ic.tag_par@chip/cpu{within(5s)};
event ereport.cpu.amd.ic_tp_trip@chip/cpu;

event fault.cpu.amd.icachetag@chip/cpu, FITrate=ICACHETAG_FIT,
	FRU=chip, ASRU=chip/cpu;

engine serd.cpu.amd.icachetag@chip/cpu,
    N=ICACHETAG_SB_COUNT, T=ICACHETAG_SB_TIME, method=persistent,
    trip=ereport.cpu.amd.ic_tp_trip@chip/cpu;

event upset.cpu.amd.icachetag@chip/cpu,
	engine=serd.cpu.amd.icachetag@chip/cpu;

prop upset.cpu.amd.icachetag@chip/cpu (1)->
    ereport.cpu.amd.ic.tag_par@chip/cpu;

prop fault.cpu.amd.icachetag@chip/cpu (1)->
    ereport.cpu.amd.ic_tp_trip@chip/cpu;

prop fault.cpu.amd.icachetag@chip/cpu (0)->
    ereport.cpu.amd.ic.tag_par@chip/cpu;

/* 								#ICT_SNOOP#
 * A snoop tag array parity fault in an I cache can cause:
 *
 *  - stag_par : reported by ic on this cpu
 */

#define ICACHESTAG_FIT		1000

event ereport.cpu.amd.ic.stag_par@chip/cpu{within(5s)};

event fault.cpu.amd.icachestag@chip/cpu, FITrate=ICACHESTAG_FIT,
	FRU=chip, ASRU=chip/cpu;

prop fault.cpu.amd.icachestag@chip/cpu (1)->
    ereport.cpu.amd.ic.stag_par@chip/cpu;

/* 								#ICTLB_1#
 * An l1tlb parity fault in an I cache can cause:
 *
 *  - l1tlb_par : reported by ic on this cpu
 */

#define ICACHEL1TLB_FIT		1000
#define ICACHEL1TLB_SB_COUNT	2
#define ICACHEL1TLB_SB_TIME	168h

event ereport.cpu.amd.ic.l1tlb_par@chip/cpu{within(5s)};
event ereport.cpu.amd.ic_l1tlb_trip@chip/cpu;

event fault.cpu.amd.l1itlb@chip/cpu, FITrate=ICACHEL1TLB_FIT,
	FRU=chip, ASRU=chip/cpu;

engine serd.cpu.amd.l1itlb@chip/cpu,
    N=ICACHEL1TLB_SB_COUNT, T=ICACHEL1TLB_SB_TIME, method=persistent,
    trip=ereport.cpu.amd.ic_l1tlb_trip@chip/cpu;

event upset.cpu.amd.l1itlb@chip/cpu,
	engine=serd.cpu.amd.l1itlb@chip/cpu;

prop upset.cpu.amd.l1itlb@chip/cpu (1)->
    ereport.cpu.amd.ic.l1tlb_par@chip/cpu;

prop fault.cpu.amd.l1itlb@chip/cpu (1)->
    ereport.cpu.amd.ic_l1tlb_trip@chip/cpu;

prop fault.cpu.amd.l1itlb@chip/cpu (0)->
    ereport.cpu.amd.ic.l1tlb_par@chip/cpu;

/* 								#ICTLB_2#
 * An l2tlb parity fault in an I cache can cause:
 *
 *  - l2tlb_par : reported by ic on this cpu
 */

#define ICACHEL2TLB_FIT		1000
#define ICACHEL2TLB_SB_COUNT	2
#define ICACHEL2TLB_SB_TIME	168h

event ereport.cpu.amd.ic.l2tlb_par@chip/cpu{within(5s)};
event ereport.cpu.amd.ic_l2tlb_trip@chip/cpu;

event fault.cpu.amd.l2itlb@chip/cpu, FITrate=ICACHEL2TLB_FIT,
	FRU=chip, ASRU=chip/cpu;

engine serd.cpu.amd.l2itlb@chip/cpu,
    N=ICACHEL2TLB_SB_COUNT, T=ICACHEL2TLB_SB_TIME, method=persistent,
    trip=ereport.cpu.amd.ic_l2tlb_trip@chip/cpu;

event upset.cpu.amd.l2itlb@chip/cpu,
	engine=serd.cpu.amd.l2itlb@chip/cpu;

prop upset.cpu.amd.l2itlb@chip/cpu (1)->
    ereport.cpu.amd.ic.l2tlb_par@chip/cpu;

prop fault.cpu.amd.l2itlb@chip/cpu (1)->
    ereport.cpu.amd.ic_l2tlb_trip@chip/cpu;

prop fault.cpu.amd.l2itlb@chip/cpu (0)->
    ereport.cpu.amd.ic.l2tlb_par@chip/cpu;

/*								#DCD#
 * dcache data errors
 */

#define DCACHEDATA_FIT		1000
#define DCACHEDATA_SB_COUNT	2
#define DCACHEDATA_SB_TIME	168h

event fault.cpu.amd.dcachedata@chip/cpu, FITrate=DCACHEDATA_FIT,
	FRU=chip, ASRU=chip/cpu;
event error.cpu.amd.dcachedata_sb@chip/cpu;
event error.cpu.amd.dcachedata_mb@chip/cpu;

prop fault.cpu.amd.dcachedata@chip/cpu (1)->
    error.cpu.amd.dcachedata_sb@chip/cpu,
    error.cpu.amd.dcachedata_mb@chip/cpu;

/* 								#DCD_SINGLE#
 * A single bit data array fault in an D cache can cause:
 *
 *  - data_ecc1 : reported by dc on this cpu by scrubber
 *  - data_ecc1_uc : reported by dc on this cpu other than by scrubber
 *
 * Make data_ecc1_uc fault immediately as it may have caused a panic
 */

event ereport.cpu.amd.dc.data_ecc1@chip/cpu{within(5s)};
event ereport.cpu.amd.dc.data_ecc1_uc@chip/cpu{within(5s)};
event ereport.cpu.amd.dc_sb_trip@chip/cpu;

engine serd.cpu.amd.dc_sb@chip/cpu,
    N=DCACHEDATA_SB_COUNT, T=DCACHEDATA_SB_TIME, method=persistent,
    trip=ereport.cpu.amd.dc_sb_trip@chip/cpu;

engine serd.cpu.amd.dc_sb_uc@chip/cpu,
    N=0, T=1hr, method=persistent,
    trip=ereport.cpu.amd.dc_sb_trip@chip/cpu;

event upset.cpu.amd.dc_sb@chip/cpu,
	engine=serd.cpu.amd.dc_sb@chip/cpu;

event upset.cpu.amd.dc_sb_uc@chip/cpu,
	engine=serd.cpu.amd.dc_sb_uc@chip/cpu;

prop upset.cpu.amd.dc_sb@chip/cpu (1)->
    ereport.cpu.amd.dc.data_ecc1@chip/cpu;

prop upset.cpu.amd.dc_sb_uc@chip/cpu (1)->
    ereport.cpu.amd.dc.data_ecc1_uc@chip/cpu;

prop error.cpu.amd.dcachedata_sb@chip/cpu (1)->
    ereport.cpu.amd.dc_sb_trip@chip/cpu;

prop fault.cpu.amd.dcachedata@chip/cpu (0)->
    ereport.cpu.amd.dc.data_ecc1@chip/cpu,
    ereport.cpu.amd.dc.data_ecc1_uc@chip/cpu;

/* 								#DCD_MULTI#
 * A multi-bit data array fault in an D cache can cause:
 *
 *  - data_eccm : reported by dc on this cpu
 */

event ereport.cpu.amd.dc.data_eccm@chip/cpu;

prop error.cpu.amd.dcachedata_mb@chip/cpu (1)->
    ereport.cpu.amd.dc.data_eccm@chip/cpu;

prop fault.cpu.amd.dcachedata@chip/cpu (0)->
    ereport.cpu.amd.dc.data_eccm@chip/cpu;

/* 								#DCT_PAR#
 * A tag array parity fault in an D cache can cause:
 *
 *  - tag_par : reported by dc on this cpu
 */

#define DCACHETAG_FIT		1000

event ereport.cpu.amd.dc.tag_par@chip/cpu{within(5s)};

event fault.cpu.amd.dcachetag@chip/cpu, FITrate=DCACHETAG_FIT,
	FRU=chip, ASRU=chip/cpu;

prop fault.cpu.amd.dcachetag@chip/cpu (1)->
    ereport.cpu.amd.dc.tag_par@chip/cpu;

/* 								#DCT_SNOOP#
 * A snoop tag array parity fault in an D cache can cause:
 *
 *  - stag_par : reported by dc on this cpu
 */

#define DCACHESTAG_FIT		1000

event ereport.cpu.amd.dc.stag_par@chip/cpu{within(5s)};

event fault.cpu.amd.dcachestag@chip/cpu, FITrate=DCACHESTAG_FIT,
	FRU=chip, ASRU=chip/cpu;

prop fault.cpu.amd.dcachestag@chip/cpu (1)->
    ereport.cpu.amd.dc.stag_par@chip/cpu;

/* 								#DCTLB_1#
 * An l1tlb parity fault in an D cache can cause:
 *
 *  - l1tlb_par : reported by dc on this cpu
 */

#define L1DTLB_FIT		1000

event ereport.cpu.amd.dc.l1tlb_par@chip/cpu{within(5s)};

event fault.cpu.amd.l1dtlb@chip/cpu, FITrate=L1DTLB_FIT,
	FRU=chip, ASRU=chip/cpu;

prop fault.cpu.amd.l1dtlb@chip/cpu (1)->
    ereport.cpu.amd.dc.l1tlb_par@chip/cpu;

/* 								#DCTLB_2#
 * An l2tlb parity fault in an D cache can cause:
 *
 *  - l2tlb_par : reported by dc on this cpu
 */

#define L2DTLB_FIT		1000

event ereport.cpu.amd.dc.l2tlb_par@chip/cpu{within(5s)};

event fault.cpu.amd.l2dtlb@chip/cpu, FITrate=L2DTLB_FIT,
	FRU=chip, ASRU=chip/cpu;

prop fault.cpu.amd.l2dtlb@chip/cpu (1)->
    ereport.cpu.amd.dc.l2tlb_par@chip/cpu;

/*								#DPATH_SB#
 * Datapath errors between NB/MC and core.
 */

#define	CPU_DP_FIT		1000

event fault.cpu.amd.datapath@chip/cpu, FITrate=CPU_DP_FIT, FRU=chip,
	ASRU=chip/cpu;
event error.cpu.amd.datapath_sb@chip/cpu;
event error.cpu.amd.datapath_mb@chip/cpu;

prop fault.cpu.amd.datapath@chip/cpu (1)->
    error.cpu.amd.datapath_sb@chip/cpu,
    error.cpu.amd.datapath_mb@chip/cpu;

/*
 * A single bit fault in the datapath between the NB and requesting core
 * can cause:
 *
 *  - inf_sys_ecc1 : reported by ic on access from a local cpu
 *  - inf_sys_ecc1 : reported by dc on access from a local cpu
 *  - s_ecc1 : reported by bu on access from a local cpu (hw prefetch etc)
 *
 * Empirical observations show that in 64/8 ECC mode some memory CEs *can*
 * travel past the DRAM controller and on to the IC/DC/BU to be reported
 * via the above errors.  This is not the case with ChipKill enabled.
 * We should not be diagnosing datapath/chip errors for these.  While
 * this behaviour is clarified the serd parameters will be set to infinity
 * (and the multibit counterpats will not be seen because of sync flood).
 */

#define	CPU_DP_COUNT	5000
#define	CPU_DP_TIME	1m

event ereport.cpu.amd.ic.inf_sys_ecc1@chip/cpu{within(5s)};
event ereport.cpu.amd.dc.inf_sys_ecc1@chip/cpu{within(5s)};
event ereport.cpu.amd.bu.s_ecc1@chip/cpu{within(5s)};
event upset.cpu.dp_sb@chip/cpu, engine=serd.cpu.dp_sb@chip/cpu;
event ereport.cpu.amd.dp_sb_trip@chip/cpu;

engine serd.cpu.dp_sb@chip/cpu, N=CPU_DP_COUNT, T=CPU_DP_TIME,
    method=persistent, trip=ereport.cpu.amd.dp_sb_trip@chip/cpu;

prop upset.cpu.dp_sb@chip/cpu (1)->
    ereport.cpu.amd.ic.inf_sys_ecc1@chip/cpu,
    ereport.cpu.amd.dc.inf_sys_ecc1@chip/cpu,
    ereport.cpu.amd.bu.s_ecc1@chip/cpu;

prop error.cpu.amd.datapath_sb@chip/cpu (1)->
    ereport.cpu.amd.dp_sb_trip@chip/cpu;

prop fault.cpu.amd.datapath@chip/cpu (0)->
    ereport.cpu.amd.ic.inf_sys_ecc1@chip/cpu,
    ereport.cpu.amd.dc.inf_sys_ecc1@chip/cpu,
    ereport.cpu.amd.bu.s_ecc1@chip/cpu;

/*								#DPATH_MB#
 * A multi-bit fault in the datapath between the NB and requesting core
 * can cause:
 *
 *  - inf_sys_eccm : reported by ic on access from a local cpu
 *  - inf_sys_eccm : reported by dc on access from a local cpu
 *  - s_eccm : reported by bu on access from a local cpu (hw prefetch etc)
 */

event ereport.cpu.amd.ic.inf_sys_eccm@chip/cpu;
event ereport.cpu.amd.dc.inf_sys_eccm@chip/cpu;
event ereport.cpu.amd.bu.s_eccm@chip/cpu;

prop error.cpu.amd.datapath_mb@chip/cpu (1)->
    ereport.cpu.amd.ic.inf_sys_eccm@chip/cpu,
    ereport.cpu.amd.dc.inf_sys_eccm@chip/cpu,
    ereport.cpu.amd.bu.s_eccm@chip/cpu;

prop fault.cpu.amd.datapath@chip/cpu (0)->
    ereport.cpu.amd.ic.inf_sys_eccm@chip/cpu,
    ereport.cpu.amd.dc.inf_sys_eccm@chip/cpu,
    ereport.cpu.amd.bu.s_eccm@chip/cpu;

/*
 * Ereports that should not normally happen and which we will discard
 * without diagnosis if they do.  These fall into a few categories:
 *
 *	- the corresponding detector is not enabled, typically because
 *	  detection/handling of the event is taking place elsewhere
 *	  (nb.ma, nb.ta, ls.rde, ic.rdde, bu.s_rde, nb.gart_walk)
 *	- the event is associated with a sync flood so even if the detector is
 *	  enabled we will never handle the event and generate an ereport *and*
 *	  even if the ereport did arrive we could perform no useful diagnosis
 *	  e.g., the NB can be configured for sync flood on nb.mem_eccm
 *	  but we don't choose to discard that ereport here since we could have
 *	  made a useful diagnosis from it had it been delivered
 *	  (nb.ht_sync, nb.ht_crc)
 *	- events that will be accompanied by an immediate panic and
 *	  delivery of the ereport during subsequent reboot but from
 *	  which no useful diagnosis can be made. (nb.rmw, nb.wdog)
 *
 * Ereports for all of these can be generated by error simulation and
 * injection.  We will perform a null diagnosos of all these ereports in order
 * to avoid "no subscription" complaints during test harness runs.
 */

event ereport.cpu.amd.nb.ma@cpu;
event ereport.cpu.amd.nb.ta@cpu;
event ereport.cpu.amd.ls.s_rde@cpu;
event ereport.cpu.amd.ic.rdde@cpu;
event ereport.cpu.amd.bu.s_rde@cpu;
event ereport.cpu.amd.nb.gart_walk@cpu;
event ereport.cpu.amd.nb.ht_sync@cpu;
event ereport.cpu.amd.nb.ht_crc@cpu;
event ereport.cpu.amd.nb.rmw@cpu;
event ereport.cpu.amd.nb.wdog@cpu;
event ereport.cpu.amd.unknown@cpu;

event upset.null_diag@cpu;

prop upset.null_diag@cpu (1)->
    ereport.cpu.amd.nb.ma@cpu,
    ereport.cpu.amd.nb.ta@cpu,
    ereport.cpu.amd.ls.s_rde@cpu,
    ereport.cpu.amd.ic.rdde@cpu,
    ereport.cpu.amd.bu.s_rde@cpu,
    ereport.cpu.amd.nb.gart_walk@cpu,
    ereport.cpu.amd.nb.ht_sync@cpu,
    ereport.cpu.amd.nb.ht_crc@cpu,
    ereport.cpu.amd.nb.rmw@cpu,
    ereport.cpu.amd.nb.wdog@cpu,
    ereport.cpu.amd.unknown@cpu;