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p4.c
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/* Copyright (c) 2005 by Intel Corp.
Decode Intel machine check (generic and P4 specific)
mcelog 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.
mcelog is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
General Public License for more details.
You should find a copy of v2 of the GNU General Public License somewhere
on your Linux system; if not, write to the Free Software Foundation,
Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
Authors:
Racing Guo <[email protected]>
Andi Kleen
*/
#include <stdio.h>
#include <stddef.h>
#include "mcelog.h"
#include "p4.h"
#include "core2.h"
#include "nehalem.h"
#include "dunnington.h"
#include "tulsa.h"
#include "intel.h"
#include "yellow.h"
#include "bus.h"
#include "unknown.h"
#include "bitfield.h"
#include "sandy-bridge.h"
#include "ivy-bridge.h"
#include "haswell.h"
#include "broadwell_de.h"
#include "broadwell_epex.h"
#include "skylake_xeon.h"
#include "denverton.h"
#include "i10nm.h"
#include "sapphire.h"
#include "granite.h"
/* decode mce for P4/Xeon and Core2 family */
static char* get_TT_str(__u8 t)
{
static char* TT[] = {"Instruction", "Data", "Generic", "Unknown"};
if (t >= NELE(TT)) {
return "UNKNOWN";
}
return TT[t];
}
static char* get_LL_str(__u8 ll)
{
static char* LL[] = {"Level-0", "Level-1", "Level-2", "Level-3"};
if (ll >= NELE(LL)) {
return "UNKNOWN";
}
return LL[ll];
}
static char* get_RRRR_str(__u8 rrrr)
{
static struct {
__u8 value;
char* str;
} RRRR [] = {
{0, "Generic"}, {1, "Read"},
{2, "Write" }, {3, "Data-Read"},
{4, "Data-Write"}, {5, "Instruction-Fetch"},
{6, "Prefetch"}, {7, "Eviction"},
{8, "Snoop"}
};
unsigned i;
for (i = 0; i < (int)NELE(RRRR); i++) {
if (RRRR[i].value == rrrr) {
return RRRR[i].str;
}
}
return "UNKNOWN";
}
static char* get_PP_str(__u8 pp)
{
static char* PP[] = {
"Local-CPU-originated-request",
"Responed-to-request",
"Observed-error-as-third-party",
"Generic"
};
if (pp >= NELE(PP)) {
return "UNKNOWN";
}
return PP[pp];
}
static char* get_T_str(__u8 t)
{
static char* T[] = {"Request-did-not-timeout", "Request-timed-out"};
if (t >= NELE(T)) {
return "UNKNOWN";
}
return T[t];
}
static char* get_II_str(__u8 i)
{
static char* II[] = {"Memory-access", "Reserved", "IO", "Other-transaction"};
if (i >= NELE(II)) {
return "UNKNOWN";
}
return II[i];
}
static int decode_mca(u64 status, u64 misc, u64 track, int cpu, int *ismemerr, int socket,
u8 bank)
{
#define TLB_LL_MASK 0x3 /*bit 0, bit 1*/
#define TLB_LL_SHIFT 0x0
#define TLB_TT_MASK 0xc /*bit 2, bit 3*/
#define TLB_TT_SHIFT 0x2
#define CACHE_LL_MASK 0x3 /*bit 0, bit 1*/
#define CACHE_LL_SHIFT 0x0
#define CACHE_TT_MASK 0xc /*bit 2, bit 3*/
#define CACHE_TT_SHIFT 0x2
#define CACHE_RRRR_MASK 0xF0 /*bit 4, bit 5, bit 6, bit 7 */
#define CACHE_RRRR_SHIFT 0x4
#define BUS_LL_MASK 0x3 /* bit 0, bit 1*/
#define BUS_LL_SHIFT 0x0
#define BUS_II_MASK 0xc /*bit 2, bit 3*/
#define BUS_II_SHIFT 0x2
#define BUS_RRRR_MASK 0xF0 /*bit 4, bit 5, bit 6, bit 7 */
#define BUS_RRRR_SHIFT 0x4
#define BUS_T_MASK 0x100 /*bit 8*/
#define BUS_T_SHIFT 0x8
#define BUS_PP_MASK 0x600 /*bit 9, bit 10*/
#define BUS_PP_SHIFT 0x9
u32 mca;
int ret = 0;
static char *msg[] = {
[0] = "No Error",
[1] = "Unclassified",
[2] = "Microcode ROM parity error",
[3] = "External error",
[4] = "FRC error",
[5] = "Internal parity error",
[6] = "SMM Handler Code Access Violation",
};
mca = status & 0xffff;
if (mca & (1UL << 12)) {
Wprintf("corrected filtering (some unreported errors in same region)\n");
mca &= ~(1UL << 12);
}
if (mca < NELE(msg)) {
Wprintf("%s\n", msg[mca]);
return ret;
}
if ((mca >> 2) == 3) {
unsigned levelnum;
char *level;
levelnum = mca & 3;
level = get_LL_str(levelnum);
Wprintf("%s Generic cache hierarchy error\n", level);
if (track == 2)
run_yellow_trigger(cpu, -1, levelnum, "unknown", level, socket);
} else if (test_prefix(4, mca)) {
unsigned levelnum, typenum;
char *level, *type;
typenum = (mca & TLB_TT_MASK) >> TLB_TT_SHIFT;
type = get_TT_str(typenum);
levelnum = (mca & TLB_LL_MASK) >> TLB_LL_SHIFT;
level = get_LL_str(levelnum);
Wprintf("%s TLB %s Error\n", type, level);
if (track == 2)
run_yellow_trigger(cpu, typenum, levelnum, type, level, socket);
} else if (test_prefix(8, mca)) {
unsigned typenum = (mca & CACHE_TT_MASK) >> CACHE_TT_SHIFT;
unsigned levelnum = ((mca & CACHE_LL_MASK) >> CACHE_LL_SHIFT) + 1;
char *type = get_TT_str(typenum);
char *level = get_LL_str(levelnum);
Wprintf("%s CACHE %s %s Error\n", type, level,
get_RRRR_str((mca & CACHE_RRRR_MASK) >>
CACHE_RRRR_SHIFT));
if (track == 2)
run_yellow_trigger(cpu, typenum, levelnum, type, level,socket);
} else if (test_prefix(9, mca) && EXTRACT(mca, 7, 8) == 1) {
Wprintf("Memory as cache: ");
decode_memory_controller(mca, bank);
} else if (test_prefix(10, mca)) {
if (mca == 0x400)
Wprintf("Internal Timer error\n");
else
Wprintf("Internal unclassified error: %x\n", mca & 0xffff);
ret = 1;
} else if (test_prefix(11, mca)) {
char *level, *pp, *rrrr, *ii, *timeout;
level = get_LL_str((mca & BUS_LL_MASK) >> BUS_LL_SHIFT);
pp = get_PP_str((mca & BUS_PP_MASK) >> BUS_PP_SHIFT);
rrrr = get_RRRR_str((mca & BUS_RRRR_MASK) >> BUS_RRRR_SHIFT);
ii = get_II_str((mca & BUS_II_MASK) >> BUS_II_SHIFT);
timeout = get_T_str((mca & BUS_T_MASK) >> BUS_T_SHIFT);
Wprintf("BUS error: %d %d %s %s %s %s %s\n", socket, cpu,
level, pp, rrrr, ii, timeout);
run_bus_trigger(socket, cpu, level, pp, rrrr, ii, timeout);
/* IO MCA - reported as bus/interconnect with specific PP,T,RRRR,II,LL values
* and MISCV set. MISC register points to root port that reported the error
* need to cross check with AER logs for more details.
* See: http://www.intel.com/content/www/us/en/architecture-and-technology/enhanced-mca-logging-xeon-paper.html
*/
if ((status & MCI_STATUS_MISCV) &&
(status & 0xefff) == 0x0e0b) {
int seg, bus, dev, fn;
seg = EXTRACT(misc, 32, 39);
bus = EXTRACT(misc, 24, 31);
dev = EXTRACT(misc, 19, 23);
fn = EXTRACT(misc, 16, 18);
Wprintf("IO MCA reported by root port %x:%02x:%02x.%x\n",
seg, bus, dev, fn);
run_iomca_trigger(socket, cpu, seg, bus, dev, fn);
}
} else if (test_prefix(7, mca)) {
decode_memory_controller(mca, bank);
*ismemerr = 1;
} else {
Wprintf("Unknown Error %x\n", mca);
ret = 1;
}
return ret;
}
static void p4_decode_model(__u32 model)
{
static struct {
int value;
char *str;
}MD []= {
{16, "FSB address parity"},
{17, "Response hard fail"},
{18, "Response parity"},
{19, "PIC and FSB data parity"},
{20, "Invalid PIC request(Signature=0xF04H)"},
{21, "Pad state machine"},
{22, "Pad strobe glitch"},
{23, "Pad address glitch"}
};
unsigned i;
Wprintf("Model:");
for (i = 0; i < NELE(MD); i++) {
if (model & (1 << MD[i].value))
Wprintf("%s\n",MD[i].str);
}
Wprintf("\n");
}
static void decode_tracking(u64 track)
{
static char *msg[] = {
[1] = "green",
[2] = "yellow\n"
"Large number of corrected cache errors. System operating, but might lead\n"
"to uncorrected errors soon",
[3] ="res3" };
if (track) {
Wprintf("Threshold based error status: %s\n", msg[track]);
}
}
static const char *arstate[4] = {
[0] = "UCNA",
[1] = "AR",
[2] = "SRAO",
[3] = "SRAR"
};
static const char *ce_types[] = {
[0] = "ecc",
[1] = "mirroring with channel failover",
[2] = "mirroring. Primary channel scrubbed successfully"
};
static int check_for_mirror(__u8 bank, __u64 status, __u64 misc)
{
switch (cputype) {
case CPU_BROADWELL_EPEX:
return bdw_epex_ce_type(bank, status, misc);
case CPU_SKYLAKE_XEON:
return skylake_s_ce_type(bank, status, misc);
case CPU_ICELAKE_XEON:
return i10nm_ce_type(bank, status, misc);
case CPU_SAPPHIRERAPIDS:
case CPU_EMERALDRAPIDS:
default:
return 0;
}
}
static int decode_mci(__u64 status, __u64 misc, int cpu, unsigned mcgcap, int *ismemerr,
int socket, __u8 bank)
{
u64 track = 0;
int i;
Wprintf("MCi status:\n");
if (!(status & MCI_STATUS_VAL))
Wprintf("Machine check not valid\n");
if (status & MCI_STATUS_OVER)
Wprintf("Error overflow\n");
if (status & MCI_STATUS_UC)
Wprintf("Uncorrected error\n");
else if ((i = check_for_mirror(bank, status, misc)))
Wprintf("Corrected error by %s\n", ce_types[i]);
else
Wprintf("Corrected error\n");
if (status & MCI_STATUS_EN)
Wprintf("Error enabled\n");
if (status & MCI_STATUS_MISCV)
Wprintf("MCi_MISC register valid\n");
if (status & MCI_STATUS_ADDRV)
Wprintf("MCi_ADDR register valid\n");
if (status & MCI_STATUS_PCC)
Wprintf("Processor context corrupt\n");
if (status & (MCI_STATUS_S|MCI_STATUS_AR))
Wprintf("%s\n", arstate[(status >> 55) & 3]);
if ((mcgcap & MCG_SER_P) && (status & MCI_STATUS_FWST)) {
Wprintf("Firmware may have updated this error\n");
}
if ((mcgcap == 0 || (mcgcap & MCG_TES_P)) && !(status & MCI_STATUS_UC)) {
track = (status >> 53) & 3;
decode_tracking(track);
}
Wprintf("MCA: ");
return decode_mca(status, misc, track, cpu, ismemerr, socket, bank);
}
static void decode_mcg(__u64 mcgstatus)
{
Wprintf("MCG status:");
if (mcgstatus & MCG_STATUS_RIPV)
Wprintf("RIPV ");
if (mcgstatus & MCG_STATUS_EIPV)
Wprintf("EIPV ");
if (mcgstatus & MCG_STATUS_MCIP)
Wprintf("MCIP ");
if (mcgstatus & MCG_STATUS_LMCES)
Wprintf("LMCE ");
Wprintf("\n");
}
static void decode_thermal(struct mce *log, int cpu)
{
if (log->status & 1) {
Gprintf(
"Processor %d heated above trip temperature. Throttling enabled.\n", cpu);
Gprintf(
"Please check your system cooling. Performance will be impacted\n");
} else {
Gprintf("Processor %d below trip temperature. Throttling disabled\n", cpu);
}
}
void decode_intel_mc(struct mce *log, int cputype, int *ismemerr, unsigned size)
{
int socket = size > offsetof(struct mce, socketid) ? (int)log->socketid : -1;
int cpu = log->extcpu ? log->extcpu : log->cpu;
if (log->bank == MCE_THERMAL_BANK) {
decode_thermal(log, cpu);
run_unknown_trigger(socket, cpu, log);
return;
}
decode_mcg(log->mcgstatus);
if (decode_mci(log->status, log->misc, cpu, log->mcgcap, ismemerr,
socket, log->bank))
run_unknown_trigger(socket, cpu, log);
if (test_prefix(11, (log->status & 0xffffL))) {
switch (cputype) {
case CPU_P6OLD:
p6old_decode_model(log->status);
break;
case CPU_DUNNINGTON:
case CPU_CORE2:
core2_decode_model(log->status);
break;
case CPU_TULSA:
case CPU_P4:
p4_decode_model(log->status & 0xffff0000L);
break;
case CPU_NEHALEM:
case CPU_XEON75XX:
core2_decode_model(log->status);
break;
}
}
/* Model specific addon information */
switch (cputype) {
case CPU_NEHALEM:
nehalem_decode_model(log->status, log->misc);
break;
case CPU_DUNNINGTON:
dunnington_decode_model(log->status);
break;
case CPU_TULSA:
tulsa_decode_model(log->status, log->misc);
break;
case CPU_XEON75XX:
xeon75xx_decode_model(log, size);
break;
case CPU_SANDY_BRIDGE:
case CPU_SANDY_BRIDGE_EP:
snb_decode_model(cputype, log->bank, log->status, log->misc);
break;
case CPU_IVY_BRIDGE_EPEX:
ivb_decode_model(cputype, log->bank, log->status, log->misc);
break;
case CPU_HASWELL_EPEX:
hsw_decode_model(cputype, log->bank, log->status, log->misc);
break;
case CPU_BROADWELL_DE:
bdw_de_decode_model(cputype, log->bank, log->status, log->misc);
break;
case CPU_BROADWELL_EPEX:
bdw_epex_decode_model(cputype, log->bank, log->status, log->misc);
break;
case CPU_SKYLAKE_XEON:
skylake_s_decode_model(cputype, log->bank, log->status, log->misc);
break;
case CPU_ICELAKE_XEON:
case CPU_ICELAKE_DE:
case CPU_TREMONT_D:
i10nm_decode_model(cputype, log->bank, log->status, log->misc);
break;
case CPU_SAPPHIRERAPIDS:
case CPU_EMERALDRAPIDS:
sapphire_decode_model(cputype, log->bank, log->status, log->misc);
break;
case CPU_GRANITERAPIDS:
case CPU_SIERRAFOREST:
granite_decode_model(cputype, log->bank, log->status, log->misc);
break;
case CPU_DENVERTON:
denverton_decode_model(cputype, log->bank, log->status, log->misc);
break;
}
}
char *intel_bank_name(int num)
{
static char bname[64];
sprintf(bname, "BANK %d", num);
return bname;
}