freebsd-nq/lib/libpmc/libpmc.c
Ruslan Bukin 230754ccca Add support for BERI statcounters.
BERI stands for Bluespec Extensible RISC Implementation, based on MIPS.

BERI has not implemented standard MIPS perfomance monitoring counters,
instead it provides statistical counters.

BERI statcounters have a several limitations:
- They can't be written
- They don't support start/stop operation
- None of hardware interrupt is provided on a counter overflow.

So make it separate to hwpmc_mips module and support process/system
counting mode only.

Sponsored by:	DARPA, AFRL
2019-09-18 16:13:50 +00:00

1895 lines
45 KiB
C

/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 2003-2008 Joseph Koshy
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/types.h>
#include <sys/param.h>
#include <sys/module.h>
#include <sys/pmc.h>
#include <sys/syscall.h>
#include <ctype.h>
#include <errno.h>
#include <err.h>
#include <fcntl.h>
#include <pmc.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <strings.h>
#include <sysexits.h>
#include <unistd.h>
#include "libpmcinternal.h"
/* Function prototypes */
#if defined(__amd64__) || defined(__i386__)
static int k8_allocate_pmc(enum pmc_event _pe, char *_ctrspec,
struct pmc_op_pmcallocate *_pmc_config);
#endif
#if defined(__amd64__) || defined(__i386__)
static int tsc_allocate_pmc(enum pmc_event _pe, char *_ctrspec,
struct pmc_op_pmcallocate *_pmc_config);
#endif
#if defined(__arm__)
#if defined(__XSCALE__)
static int xscale_allocate_pmc(enum pmc_event _pe, char *_ctrspec,
struct pmc_op_pmcallocate *_pmc_config);
#endif
static int armv7_allocate_pmc(enum pmc_event _pe, char *_ctrspec,
struct pmc_op_pmcallocate *_pmc_config);
#endif
#if defined(__aarch64__)
static int arm64_allocate_pmc(enum pmc_event _pe, char *_ctrspec,
struct pmc_op_pmcallocate *_pmc_config);
#endif
#if defined(__mips__)
static int mips_allocate_pmc(enum pmc_event _pe, char* ctrspec,
struct pmc_op_pmcallocate *_pmc_config);
#endif /* __mips__ */
static int soft_allocate_pmc(enum pmc_event _pe, char *_ctrspec,
struct pmc_op_pmcallocate *_pmc_config);
#if defined(__powerpc__)
static int powerpc_allocate_pmc(enum pmc_event _pe, char* ctrspec,
struct pmc_op_pmcallocate *_pmc_config);
#endif /* __powerpc__ */
#define PMC_CALL(cmd, params) \
syscall(pmc_syscall, PMC_OP_##cmd, (params))
/*
* Event aliases provide a way for the user to ask for generic events
* like "cache-misses", or "instructions-retired". These aliases are
* mapped to the appropriate canonical event descriptions using a
* lookup table.
*/
struct pmc_event_alias {
const char *pm_alias;
const char *pm_spec;
};
static const struct pmc_event_alias *pmc_mdep_event_aliases;
/*
* The pmc_event_descr structure maps symbolic names known to the user
* to integer codes used by the PMC KLD.
*/
struct pmc_event_descr {
const char *pm_ev_name;
enum pmc_event pm_ev_code;
};
/*
* The pmc_class_descr structure maps class name prefixes for
* event names to event tables and other PMC class data.
*/
struct pmc_class_descr {
const char *pm_evc_name;
size_t pm_evc_name_size;
enum pmc_class pm_evc_class;
const struct pmc_event_descr *pm_evc_event_table;
size_t pm_evc_event_table_size;
int (*pm_evc_allocate_pmc)(enum pmc_event _pe,
char *_ctrspec, struct pmc_op_pmcallocate *_pa);
};
#define PMC_TABLE_SIZE(N) (sizeof(N)/sizeof(N[0]))
#define PMC_EVENT_TABLE_SIZE(N) PMC_TABLE_SIZE(N##_event_table)
#undef __PMC_EV
#define __PMC_EV(C,N) { #N, PMC_EV_ ## C ## _ ## N },
/*
* PMC_CLASSDEP_TABLE(NAME, CLASS)
*
* Define a table mapping event names and aliases to HWPMC event IDs.
*/
#define PMC_CLASSDEP_TABLE(N, C) \
static const struct pmc_event_descr N##_event_table[] = \
{ \
__PMC_EV_##C() \
}
PMC_CLASSDEP_TABLE(iaf, IAF);
PMC_CLASSDEP_TABLE(k8, K8);
PMC_CLASSDEP_TABLE(xscale, XSCALE);
PMC_CLASSDEP_TABLE(armv7, ARMV7);
PMC_CLASSDEP_TABLE(armv8, ARMV8);
PMC_CLASSDEP_TABLE(beri, BERI);
PMC_CLASSDEP_TABLE(mips24k, MIPS24K);
PMC_CLASSDEP_TABLE(mips74k, MIPS74K);
PMC_CLASSDEP_TABLE(octeon, OCTEON);
PMC_CLASSDEP_TABLE(ppc7450, PPC7450);
PMC_CLASSDEP_TABLE(ppc970, PPC970);
PMC_CLASSDEP_TABLE(e500, E500);
static struct pmc_event_descr soft_event_table[PMC_EV_DYN_COUNT];
#undef __PMC_EV_ALIAS
#define __PMC_EV_ALIAS(N,CODE) { N, PMC_EV_##CODE },
static const struct pmc_event_descr cortex_a8_event_table[] =
{
__PMC_EV_ALIAS_ARMV7_CORTEX_A8()
};
static const struct pmc_event_descr cortex_a9_event_table[] =
{
__PMC_EV_ALIAS_ARMV7_CORTEX_A9()
};
static const struct pmc_event_descr cortex_a53_event_table[] =
{
__PMC_EV_ALIAS_ARMV8_CORTEX_A53()
};
static const struct pmc_event_descr cortex_a57_event_table[] =
{
__PMC_EV_ALIAS_ARMV8_CORTEX_A57()
};
/*
* PMC_MDEP_TABLE(NAME, PRIMARYCLASS, ADDITIONAL_CLASSES...)
*
* Map a CPU to the PMC classes it supports.
*/
#define PMC_MDEP_TABLE(N,C,...) \
static const enum pmc_class N##_pmc_classes[] = { \
PMC_CLASS_##C, __VA_ARGS__ \
}
PMC_MDEP_TABLE(k8, K8, PMC_CLASS_SOFT, PMC_CLASS_TSC);
PMC_MDEP_TABLE(xscale, XSCALE, PMC_CLASS_SOFT, PMC_CLASS_XSCALE);
PMC_MDEP_TABLE(beri, BERI, PMC_CLASS_SOFT, PMC_CLASS_BERI);
PMC_MDEP_TABLE(cortex_a8, ARMV7, PMC_CLASS_SOFT, PMC_CLASS_ARMV7);
PMC_MDEP_TABLE(cortex_a9, ARMV7, PMC_CLASS_SOFT, PMC_CLASS_ARMV7);
PMC_MDEP_TABLE(cortex_a53, ARMV8, PMC_CLASS_SOFT, PMC_CLASS_ARMV8);
PMC_MDEP_TABLE(cortex_a57, ARMV8, PMC_CLASS_SOFT, PMC_CLASS_ARMV8);
PMC_MDEP_TABLE(mips24k, MIPS24K, PMC_CLASS_SOFT, PMC_CLASS_MIPS24K);
PMC_MDEP_TABLE(mips74k, MIPS74K, PMC_CLASS_SOFT, PMC_CLASS_MIPS74K);
PMC_MDEP_TABLE(octeon, OCTEON, PMC_CLASS_SOFT, PMC_CLASS_OCTEON);
PMC_MDEP_TABLE(ppc7450, PPC7450, PMC_CLASS_SOFT, PMC_CLASS_PPC7450, PMC_CLASS_TSC);
PMC_MDEP_TABLE(ppc970, PPC970, PMC_CLASS_SOFT, PMC_CLASS_PPC970, PMC_CLASS_TSC);
PMC_MDEP_TABLE(e500, E500, PMC_CLASS_SOFT, PMC_CLASS_E500, PMC_CLASS_TSC);
PMC_MDEP_TABLE(generic, SOFT, PMC_CLASS_SOFT);
static const struct pmc_event_descr tsc_event_table[] =
{
__PMC_EV_TSC()
};
#undef PMC_CLASS_TABLE_DESC
#define PMC_CLASS_TABLE_DESC(NAME, CLASS, EVENTS, ALLOCATOR) \
static const struct pmc_class_descr NAME##_class_table_descr = \
{ \
.pm_evc_name = #CLASS "-", \
.pm_evc_name_size = sizeof(#CLASS "-") - 1, \
.pm_evc_class = PMC_CLASS_##CLASS , \
.pm_evc_event_table = EVENTS##_event_table , \
.pm_evc_event_table_size = \
PMC_EVENT_TABLE_SIZE(EVENTS), \
.pm_evc_allocate_pmc = ALLOCATOR##_allocate_pmc \
}
#if defined(__i386__) || defined(__amd64__)
PMC_CLASS_TABLE_DESC(k8, K8, k8, k8);
#endif
#if defined(__i386__) || defined(__amd64__)
PMC_CLASS_TABLE_DESC(tsc, TSC, tsc, tsc);
#endif
#if defined(__arm__)
#if defined(__XSCALE__)
PMC_CLASS_TABLE_DESC(xscale, XSCALE, xscale, xscale);
#endif
PMC_CLASS_TABLE_DESC(cortex_a8, ARMV7, cortex_a8, armv7);
PMC_CLASS_TABLE_DESC(cortex_a9, ARMV7, cortex_a9, armv7);
#endif
#if defined(__aarch64__)
PMC_CLASS_TABLE_DESC(cortex_a53, ARMV8, cortex_a53, arm64);
PMC_CLASS_TABLE_DESC(cortex_a57, ARMV8, cortex_a57, arm64);
#endif
#if defined(__mips__)
PMC_CLASS_TABLE_DESC(beri, BERI, beri, mips);
PMC_CLASS_TABLE_DESC(mips24k, MIPS24K, mips24k, mips);
PMC_CLASS_TABLE_DESC(mips74k, MIPS74K, mips74k, mips);
PMC_CLASS_TABLE_DESC(octeon, OCTEON, octeon, mips);
#endif /* __mips__ */
#if defined(__powerpc__)
PMC_CLASS_TABLE_DESC(ppc7450, PPC7450, ppc7450, powerpc);
PMC_CLASS_TABLE_DESC(ppc970, PPC970, ppc970, powerpc);
PMC_CLASS_TABLE_DESC(e500, E500, e500, powerpc);
#endif
static struct pmc_class_descr soft_class_table_descr =
{
.pm_evc_name = "SOFT-",
.pm_evc_name_size = sizeof("SOFT-") - 1,
.pm_evc_class = PMC_CLASS_SOFT,
.pm_evc_event_table = NULL,
.pm_evc_event_table_size = 0,
.pm_evc_allocate_pmc = soft_allocate_pmc
};
#undef PMC_CLASS_TABLE_DESC
static const struct pmc_class_descr **pmc_class_table;
#define PMC_CLASS_TABLE_SIZE cpu_info.pm_nclass
static const enum pmc_class *pmc_mdep_class_list;
static size_t pmc_mdep_class_list_size;
/*
* Mapping tables, mapping enumeration values to human readable
* strings.
*/
static const char * pmc_capability_names[] = {
#undef __PMC_CAP
#define __PMC_CAP(N,V,D) #N ,
__PMC_CAPS()
};
struct pmc_class_map {
enum pmc_class pm_class;
const char *pm_name;
};
static const struct pmc_class_map pmc_class_names[] = {
#undef __PMC_CLASS
#define __PMC_CLASS(S,V,D) { .pm_class = PMC_CLASS_##S, .pm_name = #S } ,
__PMC_CLASSES()
};
struct pmc_cputype_map {
enum pmc_cputype pm_cputype;
const char *pm_name;
};
static const struct pmc_cputype_map pmc_cputype_names[] = {
#undef __PMC_CPU
#define __PMC_CPU(S, V, D) { .pm_cputype = PMC_CPU_##S, .pm_name = #S } ,
__PMC_CPUS()
};
static const char * pmc_disposition_names[] = {
#undef __PMC_DISP
#define __PMC_DISP(D) #D ,
__PMC_DISPOSITIONS()
};
static const char * pmc_mode_names[] = {
#undef __PMC_MODE
#define __PMC_MODE(M,N) #M ,
__PMC_MODES()
};
static const char * pmc_state_names[] = {
#undef __PMC_STATE
#define __PMC_STATE(S) #S ,
__PMC_STATES()
};
/*
* Filled in by pmc_init().
*/
static int pmc_syscall = -1;
static struct pmc_cpuinfo cpu_info;
static struct pmc_op_getdyneventinfo soft_event_info;
/* Event masks for events */
struct pmc_masks {
const char *pm_name;
const uint64_t pm_value;
};
#define PMCMASK(N,V) { .pm_name = #N, .pm_value = (V) }
#define NULLMASK { .pm_name = NULL }
#if defined(__amd64__) || defined(__i386__)
static int
pmc_parse_mask(const struct pmc_masks *pmask, char *p, uint64_t *evmask)
{
const struct pmc_masks *pm;
char *q, *r;
int c;
if (pmask == NULL) /* no mask keywords */
return (-1);
q = strchr(p, '='); /* skip '=' */
if (*++q == '\0') /* no more data */
return (-1);
c = 0; /* count of mask keywords seen */
while ((r = strsep(&q, "+")) != NULL) {
for (pm = pmask; pm->pm_name && strcasecmp(r, pm->pm_name);
pm++)
;
if (pm->pm_name == NULL) /* not found */
return (-1);
*evmask |= pm->pm_value;
c++;
}
return (c);
}
#endif
#define KWMATCH(p,kw) (strcasecmp((p), (kw)) == 0)
#define KWPREFIXMATCH(p,kw) (strncasecmp((p), (kw), sizeof((kw)) - 1) == 0)
#define EV_ALIAS(N,S) { .pm_alias = N, .pm_spec = S }
#if defined(__amd64__) || defined(__i386__)
/*
* AMD K8 PMCs.
*
*/
static struct pmc_event_alias k8_aliases[] = {
EV_ALIAS("branches", "k8-fr-retired-taken-branches"),
EV_ALIAS("branch-mispredicts",
"k8-fr-retired-taken-branches-mispredicted"),
EV_ALIAS("cycles", "tsc"),
EV_ALIAS("dc-misses", "k8-dc-miss"),
EV_ALIAS("ic-misses", "k8-ic-miss"),
EV_ALIAS("instructions", "k8-fr-retired-x86-instructions"),
EV_ALIAS("interrupts", "k8-fr-taken-hardware-interrupts"),
EV_ALIAS("unhalted-cycles", "k8-bu-cpu-clk-unhalted"),
EV_ALIAS(NULL, NULL)
};
#define __K8MASK(N,V) PMCMASK(N,(1 << (V)))
/*
* Parsing tables
*/
/* fp dispatched fpu ops */
static const struct pmc_masks k8_mask_fdfo[] = {
__K8MASK(add-pipe-excluding-junk-ops, 0),
__K8MASK(multiply-pipe-excluding-junk-ops, 1),
__K8MASK(store-pipe-excluding-junk-ops, 2),
__K8MASK(add-pipe-junk-ops, 3),
__K8MASK(multiply-pipe-junk-ops, 4),
__K8MASK(store-pipe-junk-ops, 5),
NULLMASK
};
/* ls segment register loads */
static const struct pmc_masks k8_mask_lsrl[] = {
__K8MASK(es, 0),
__K8MASK(cs, 1),
__K8MASK(ss, 2),
__K8MASK(ds, 3),
__K8MASK(fs, 4),
__K8MASK(gs, 5),
__K8MASK(hs, 6),
NULLMASK
};
/* ls locked operation */
static const struct pmc_masks k8_mask_llo[] = {
__K8MASK(locked-instructions, 0),
__K8MASK(cycles-in-request, 1),
__K8MASK(cycles-to-complete, 2),
NULLMASK
};
/* dc refill from {l2,system} and dc copyback */
static const struct pmc_masks k8_mask_dc[] = {
__K8MASK(invalid, 0),
__K8MASK(shared, 1),
__K8MASK(exclusive, 2),
__K8MASK(owner, 3),
__K8MASK(modified, 4),
NULLMASK
};
/* dc one bit ecc error */
static const struct pmc_masks k8_mask_dobee[] = {
__K8MASK(scrubber, 0),
__K8MASK(piggyback, 1),
NULLMASK
};
/* dc dispatched prefetch instructions */
static const struct pmc_masks k8_mask_ddpi[] = {
__K8MASK(load, 0),
__K8MASK(store, 1),
__K8MASK(nta, 2),
NULLMASK
};
/* dc dcache accesses by locks */
static const struct pmc_masks k8_mask_dabl[] = {
__K8MASK(accesses, 0),
__K8MASK(misses, 1),
NULLMASK
};
/* bu internal l2 request */
static const struct pmc_masks k8_mask_bilr[] = {
__K8MASK(ic-fill, 0),
__K8MASK(dc-fill, 1),
__K8MASK(tlb-reload, 2),
__K8MASK(tag-snoop, 3),
__K8MASK(cancelled, 4),
NULLMASK
};
/* bu fill request l2 miss */
static const struct pmc_masks k8_mask_bfrlm[] = {
__K8MASK(ic-fill, 0),
__K8MASK(dc-fill, 1),
__K8MASK(tlb-reload, 2),
NULLMASK
};
/* bu fill into l2 */
static const struct pmc_masks k8_mask_bfil[] = {
__K8MASK(dirty-l2-victim, 0),
__K8MASK(victim-from-l2, 1),
NULLMASK
};
/* fr retired fpu instructions */
static const struct pmc_masks k8_mask_frfi[] = {
__K8MASK(x87, 0),
__K8MASK(mmx-3dnow, 1),
__K8MASK(packed-sse-sse2, 2),
__K8MASK(scalar-sse-sse2, 3),
NULLMASK
};
/* fr retired fastpath double op instructions */
static const struct pmc_masks k8_mask_frfdoi[] = {
__K8MASK(low-op-pos-0, 0),
__K8MASK(low-op-pos-1, 1),
__K8MASK(low-op-pos-2, 2),
NULLMASK
};
/* fr fpu exceptions */
static const struct pmc_masks k8_mask_ffe[] = {
__K8MASK(x87-reclass-microfaults, 0),
__K8MASK(sse-retype-microfaults, 1),
__K8MASK(sse-reclass-microfaults, 2),
__K8MASK(sse-and-x87-microtraps, 3),
NULLMASK
};
/* nb memory controller page access event */
static const struct pmc_masks k8_mask_nmcpae[] = {
__K8MASK(page-hit, 0),
__K8MASK(page-miss, 1),
__K8MASK(page-conflict, 2),
NULLMASK
};
/* nb memory controller turnaround */
static const struct pmc_masks k8_mask_nmct[] = {
__K8MASK(dimm-turnaround, 0),
__K8MASK(read-to-write-turnaround, 1),
__K8MASK(write-to-read-turnaround, 2),
NULLMASK
};
/* nb memory controller bypass saturation */
static const struct pmc_masks k8_mask_nmcbs[] = {
__K8MASK(memory-controller-hi-pri-bypass, 0),
__K8MASK(memory-controller-lo-pri-bypass, 1),
__K8MASK(dram-controller-interface-bypass, 2),
__K8MASK(dram-controller-queue-bypass, 3),
NULLMASK
};
/* nb sized commands */
static const struct pmc_masks k8_mask_nsc[] = {
__K8MASK(nonpostwrszbyte, 0),
__K8MASK(nonpostwrszdword, 1),
__K8MASK(postwrszbyte, 2),
__K8MASK(postwrszdword, 3),
__K8MASK(rdszbyte, 4),
__K8MASK(rdszdword, 5),
__K8MASK(rdmodwr, 6),
NULLMASK
};
/* nb probe result */
static const struct pmc_masks k8_mask_npr[] = {
__K8MASK(probe-miss, 0),
__K8MASK(probe-hit, 1),
__K8MASK(probe-hit-dirty-no-memory-cancel, 2),
__K8MASK(probe-hit-dirty-with-memory-cancel, 3),
NULLMASK
};
/* nb hypertransport bus bandwidth */
static const struct pmc_masks k8_mask_nhbb[] = { /* HT bus bandwidth */
__K8MASK(command, 0),
__K8MASK(data, 1),
__K8MASK(buffer-release, 2),
__K8MASK(nop, 3),
NULLMASK
};
#undef __K8MASK
#define K8_KW_COUNT "count"
#define K8_KW_EDGE "edge"
#define K8_KW_INV "inv"
#define K8_KW_MASK "mask"
#define K8_KW_OS "os"
#define K8_KW_USR "usr"
static int
k8_allocate_pmc(enum pmc_event pe, char *ctrspec,
struct pmc_op_pmcallocate *pmc_config)
{
char *e, *p, *q;
int n;
uint32_t count;
uint64_t evmask;
const struct pmc_masks *pm, *pmask;
pmc_config->pm_caps |= (PMC_CAP_READ | PMC_CAP_WRITE);
pmc_config->pm_md.pm_amd.pm_amd_config = 0;
pmask = NULL;
evmask = 0;
#define __K8SETMASK(M) pmask = k8_mask_##M
/* setup parsing tables */
switch (pe) {
case PMC_EV_K8_FP_DISPATCHED_FPU_OPS:
__K8SETMASK(fdfo);
break;
case PMC_EV_K8_LS_SEGMENT_REGISTER_LOAD:
__K8SETMASK(lsrl);
break;
case PMC_EV_K8_LS_LOCKED_OPERATION:
__K8SETMASK(llo);
break;
case PMC_EV_K8_DC_REFILL_FROM_L2:
case PMC_EV_K8_DC_REFILL_FROM_SYSTEM:
case PMC_EV_K8_DC_COPYBACK:
__K8SETMASK(dc);
break;
case PMC_EV_K8_DC_ONE_BIT_ECC_ERROR:
__K8SETMASK(dobee);
break;
case PMC_EV_K8_DC_DISPATCHED_PREFETCH_INSTRUCTIONS:
__K8SETMASK(ddpi);
break;
case PMC_EV_K8_DC_DCACHE_ACCESSES_BY_LOCKS:
__K8SETMASK(dabl);
break;
case PMC_EV_K8_BU_INTERNAL_L2_REQUEST:
__K8SETMASK(bilr);
break;
case PMC_EV_K8_BU_FILL_REQUEST_L2_MISS:
__K8SETMASK(bfrlm);
break;
case PMC_EV_K8_BU_FILL_INTO_L2:
__K8SETMASK(bfil);
break;
case PMC_EV_K8_FR_RETIRED_FPU_INSTRUCTIONS:
__K8SETMASK(frfi);
break;
case PMC_EV_K8_FR_RETIRED_FASTPATH_DOUBLE_OP_INSTRUCTIONS:
__K8SETMASK(frfdoi);
break;
case PMC_EV_K8_FR_FPU_EXCEPTIONS:
__K8SETMASK(ffe);
break;
case PMC_EV_K8_NB_MEMORY_CONTROLLER_PAGE_ACCESS_EVENT:
__K8SETMASK(nmcpae);
break;
case PMC_EV_K8_NB_MEMORY_CONTROLLER_TURNAROUND:
__K8SETMASK(nmct);
break;
case PMC_EV_K8_NB_MEMORY_CONTROLLER_BYPASS_SATURATION:
__K8SETMASK(nmcbs);
break;
case PMC_EV_K8_NB_SIZED_COMMANDS:
__K8SETMASK(nsc);
break;
case PMC_EV_K8_NB_PROBE_RESULT:
__K8SETMASK(npr);
break;
case PMC_EV_K8_NB_HT_BUS0_BANDWIDTH:
case PMC_EV_K8_NB_HT_BUS1_BANDWIDTH:
case PMC_EV_K8_NB_HT_BUS2_BANDWIDTH:
__K8SETMASK(nhbb);
break;
default:
break; /* no options defined */
}
while ((p = strsep(&ctrspec, ",")) != NULL) {
if (KWPREFIXMATCH(p, K8_KW_COUNT "=")) {
q = strchr(p, '=');
if (*++q == '\0') /* skip '=' */
return (-1);
count = strtol(q, &e, 0);
if (e == q || *e != '\0')
return (-1);
pmc_config->pm_caps |= PMC_CAP_THRESHOLD;
pmc_config->pm_md.pm_amd.pm_amd_config |=
AMD_PMC_TO_COUNTER(count);
} else if (KWMATCH(p, K8_KW_EDGE)) {
pmc_config->pm_caps |= PMC_CAP_EDGE;
} else if (KWMATCH(p, K8_KW_INV)) {
pmc_config->pm_caps |= PMC_CAP_INVERT;
} else if (KWPREFIXMATCH(p, K8_KW_MASK "=")) {
if ((n = pmc_parse_mask(pmask, p, &evmask)) < 0)
return (-1);
pmc_config->pm_caps |= PMC_CAP_QUALIFIER;
} else if (KWMATCH(p, K8_KW_OS)) {
pmc_config->pm_caps |= PMC_CAP_SYSTEM;
} else if (KWMATCH(p, K8_KW_USR)) {
pmc_config->pm_caps |= PMC_CAP_USER;
} else
return (-1);
}
/* other post processing */
switch (pe) {
case PMC_EV_K8_FP_DISPATCHED_FPU_OPS:
case PMC_EV_K8_FP_CYCLES_WITH_NO_FPU_OPS_RETIRED:
case PMC_EV_K8_FP_DISPATCHED_FPU_FAST_FLAG_OPS:
case PMC_EV_K8_FR_RETIRED_FASTPATH_DOUBLE_OP_INSTRUCTIONS:
case PMC_EV_K8_FR_RETIRED_FPU_INSTRUCTIONS:
case PMC_EV_K8_FR_FPU_EXCEPTIONS:
/* XXX only available in rev B and later */
break;
case PMC_EV_K8_DC_DCACHE_ACCESSES_BY_LOCKS:
/* XXX only available in rev C and later */
break;
case PMC_EV_K8_LS_LOCKED_OPERATION:
/* XXX CPU Rev A,B evmask is to be zero */
if (evmask & (evmask - 1)) /* > 1 bit set */
return (-1);
if (evmask == 0) {
evmask = 0x01; /* Rev C and later: #instrs */
pmc_config->pm_caps |= PMC_CAP_QUALIFIER;
}
break;
default:
if (evmask == 0 && pmask != NULL) {
for (pm = pmask; pm->pm_name; pm++)
evmask |= pm->pm_value;
pmc_config->pm_caps |= PMC_CAP_QUALIFIER;
}
}
if (pmc_config->pm_caps & PMC_CAP_QUALIFIER)
pmc_config->pm_md.pm_amd.pm_amd_config =
AMD_PMC_TO_UNITMASK(evmask);
return (0);
}
#endif
#if defined(__i386__) || defined(__amd64__)
static int
tsc_allocate_pmc(enum pmc_event pe, char *ctrspec,
struct pmc_op_pmcallocate *pmc_config)
{
if (pe != PMC_EV_TSC_TSC)
return (-1);
/* TSC events must be unqualified. */
if (ctrspec && *ctrspec != '\0')
return (-1);
pmc_config->pm_md.pm_amd.pm_amd_config = 0;
pmc_config->pm_caps |= PMC_CAP_READ;
return (0);
}
#endif
static struct pmc_event_alias generic_aliases[] = {
EV_ALIAS("instructions", "SOFT-CLOCK.HARD"),
EV_ALIAS(NULL, NULL)
};
static int
soft_allocate_pmc(enum pmc_event pe, char *ctrspec,
struct pmc_op_pmcallocate *pmc_config)
{
(void)ctrspec;
(void)pmc_config;
if ((int)pe < PMC_EV_SOFT_FIRST || (int)pe > PMC_EV_SOFT_LAST)
return (-1);
pmc_config->pm_caps |= (PMC_CAP_READ | PMC_CAP_WRITE);
return (0);
}
#if defined(__arm__)
#if defined(__XSCALE__)
static struct pmc_event_alias xscale_aliases[] = {
EV_ALIAS("branches", "BRANCH_RETIRED"),
EV_ALIAS("branch-mispredicts", "BRANCH_MISPRED"),
EV_ALIAS("dc-misses", "DC_MISS"),
EV_ALIAS("ic-misses", "IC_MISS"),
EV_ALIAS("instructions", "INSTR_RETIRED"),
EV_ALIAS(NULL, NULL)
};
static int
xscale_allocate_pmc(enum pmc_event pe, char *ctrspec __unused,
struct pmc_op_pmcallocate *pmc_config __unused)
{
switch (pe) {
default:
break;
}
return (0);
}
#endif
static struct pmc_event_alias cortex_a8_aliases[] = {
EV_ALIAS("dc-misses", "L1_DCACHE_REFILL"),
EV_ALIAS("ic-misses", "L1_ICACHE_REFILL"),
EV_ALIAS("instructions", "INSTR_EXECUTED"),
EV_ALIAS(NULL, NULL)
};
static struct pmc_event_alias cortex_a9_aliases[] = {
EV_ALIAS("dc-misses", "L1_DCACHE_REFILL"),
EV_ALIAS("ic-misses", "L1_ICACHE_REFILL"),
EV_ALIAS("instructions", "INSTR_EXECUTED"),
EV_ALIAS(NULL, NULL)
};
static int
armv7_allocate_pmc(enum pmc_event pe, char *ctrspec __unused,
struct pmc_op_pmcallocate *pmc_config __unused)
{
switch (pe) {
default:
break;
}
return (0);
}
#endif
#if defined(__aarch64__)
static struct pmc_event_alias cortex_a53_aliases[] = {
EV_ALIAS(NULL, NULL)
};
static struct pmc_event_alias cortex_a57_aliases[] = {
EV_ALIAS(NULL, NULL)
};
static int
arm64_allocate_pmc(enum pmc_event pe, char *ctrspec __unused,
struct pmc_op_pmcallocate *pmc_config __unused)
{
switch (pe) {
default:
break;
}
return (0);
}
#endif
#if defined(__mips__)
static struct pmc_event_alias beri_aliases[] = {
EV_ALIAS("instructions", "INST"),
EV_ALIAS(NULL, NULL)
};
static struct pmc_event_alias mips24k_aliases[] = {
EV_ALIAS("instructions", "INSTR_EXECUTED"),
EV_ALIAS("branches", "BRANCH_COMPLETED"),
EV_ALIAS("branch-mispredicts", "BRANCH_MISPRED"),
EV_ALIAS(NULL, NULL)
};
static struct pmc_event_alias mips74k_aliases[] = {
EV_ALIAS("instructions", "INSTR_EXECUTED"),
EV_ALIAS("branches", "BRANCH_INSNS"),
EV_ALIAS("branch-mispredicts", "MISPREDICTED_BRANCH_INSNS"),
EV_ALIAS(NULL, NULL)
};
static struct pmc_event_alias octeon_aliases[] = {
EV_ALIAS("instructions", "RET"),
EV_ALIAS("branches", "BR"),
EV_ALIAS("branch-mispredicts", "BRMIS"),
EV_ALIAS(NULL, NULL)
};
#define MIPS_KW_OS "os"
#define MIPS_KW_USR "usr"
#define MIPS_KW_ANYTHREAD "anythread"
static int
mips_allocate_pmc(enum pmc_event pe, char *ctrspec __unused,
struct pmc_op_pmcallocate *pmc_config __unused)
{
char *p;
(void) pe;
pmc_config->pm_caps |= (PMC_CAP_READ | PMC_CAP_WRITE);
while ((p = strsep(&ctrspec, ",")) != NULL) {
if (KWMATCH(p, MIPS_KW_OS))
pmc_config->pm_caps |= PMC_CAP_SYSTEM;
else if (KWMATCH(p, MIPS_KW_USR))
pmc_config->pm_caps |= PMC_CAP_USER;
else if (KWMATCH(p, MIPS_KW_ANYTHREAD))
pmc_config->pm_caps |= (PMC_CAP_USER | PMC_CAP_SYSTEM);
else
return (-1);
}
return (0);
}
#endif /* __mips__ */
#if defined(__powerpc__)
static struct pmc_event_alias ppc7450_aliases[] = {
EV_ALIAS("instructions", "INSTR_COMPLETED"),
EV_ALIAS("branches", "BRANCHES_COMPLETED"),
EV_ALIAS("branch-mispredicts", "MISPREDICTED_BRANCHES"),
EV_ALIAS(NULL, NULL)
};
static struct pmc_event_alias ppc970_aliases[] = {
EV_ALIAS("instructions", "INSTR_COMPLETED"),
EV_ALIAS("cycles", "CYCLES"),
EV_ALIAS(NULL, NULL)
};
static struct pmc_event_alias e500_aliases[] = {
EV_ALIAS("instructions", "INSTR_COMPLETED"),
EV_ALIAS("cycles", "CYCLES"),
EV_ALIAS(NULL, NULL)
};
#define POWERPC_KW_OS "os"
#define POWERPC_KW_USR "usr"
#define POWERPC_KW_ANYTHREAD "anythread"
static int
powerpc_allocate_pmc(enum pmc_event pe, char *ctrspec __unused,
struct pmc_op_pmcallocate *pmc_config __unused)
{
char *p;
(void) pe;
pmc_config->pm_caps |= (PMC_CAP_READ | PMC_CAP_WRITE);
while ((p = strsep(&ctrspec, ",")) != NULL) {
if (KWMATCH(p, POWERPC_KW_OS))
pmc_config->pm_caps |= PMC_CAP_SYSTEM;
else if (KWMATCH(p, POWERPC_KW_USR))
pmc_config->pm_caps |= PMC_CAP_USER;
else if (KWMATCH(p, POWERPC_KW_ANYTHREAD))
pmc_config->pm_caps |= (PMC_CAP_USER | PMC_CAP_SYSTEM);
else
return (-1);
}
return (0);
}
#endif /* __powerpc__ */
/*
* Match an event name `name' with its canonical form.
*
* Matches are case insensitive and spaces, periods, underscores and
* hyphen characters are considered to match each other.
*
* Returns 1 for a match, 0 otherwise.
*/
static int
pmc_match_event_name(const char *name, const char *canonicalname)
{
int cc, nc;
const unsigned char *c, *n;
c = (const unsigned char *) canonicalname;
n = (const unsigned char *) name;
for (; (nc = *n) && (cc = *c); n++, c++) {
if ((nc == ' ' || nc == '_' || nc == '-' || nc == '.') &&
(cc == ' ' || cc == '_' || cc == '-' || cc == '.'))
continue;
if (toupper(nc) == toupper(cc))
continue;
return (0);
}
if (*n == '\0' && *c == '\0')
return (1);
return (0);
}
/*
* Match an event name against all the event named supported by a
* PMC class.
*
* Returns an event descriptor pointer on match or NULL otherwise.
*/
static const struct pmc_event_descr *
pmc_match_event_class(const char *name,
const struct pmc_class_descr *pcd)
{
size_t n;
const struct pmc_event_descr *ev;
ev = pcd->pm_evc_event_table;
for (n = 0; n < pcd->pm_evc_event_table_size; n++, ev++)
if (pmc_match_event_name(name, ev->pm_ev_name))
return (ev);
return (NULL);
}
static int
pmc_mdep_is_compatible_class(enum pmc_class pc)
{
size_t n;
for (n = 0; n < pmc_mdep_class_list_size; n++)
if (pmc_mdep_class_list[n] == pc)
return (1);
return (0);
}
/*
* API entry points
*/
int
pmc_allocate(const char *ctrspec, enum pmc_mode mode,
uint32_t flags, int cpu, pmc_id_t *pmcid,
uint64_t count)
{
size_t n;
int retval;
char *r, *spec_copy;
const char *ctrname;
const struct pmc_event_descr *ev;
const struct pmc_event_alias *alias;
struct pmc_op_pmcallocate pmc_config;
const struct pmc_class_descr *pcd;
spec_copy = NULL;
retval = -1;
if (mode != PMC_MODE_SS && mode != PMC_MODE_TS &&
mode != PMC_MODE_SC && mode != PMC_MODE_TC) {
errno = EINVAL;
goto out;
}
bzero(&pmc_config, sizeof(pmc_config));
pmc_config.pm_cpu = cpu;
pmc_config.pm_mode = mode;
pmc_config.pm_flags = flags;
pmc_config.pm_count = count;
if (PMC_IS_SAMPLING_MODE(mode))
pmc_config.pm_caps |= PMC_CAP_INTERRUPT;
/*
* Can we pull this straight from the pmu table?
*/
r = spec_copy = strdup(ctrspec);
ctrname = strsep(&r, ",");
if (pmc_pmu_enabled()) {
if (pmc_pmu_pmcallocate(ctrname, &pmc_config) == 0) {
if (PMC_CALL(PMCALLOCATE, &pmc_config) < 0) {
goto out;
}
retval = 0;
*pmcid = pmc_config.pm_pmcid;
goto out;
}
errx(EX_USAGE, "ERROR: pmc_pmu_allocate failed, check for ctrname %s\n", ctrname);
} else {
free(spec_copy);
spec_copy = NULL;
}
/* replace an event alias with the canonical event specifier */
if (pmc_mdep_event_aliases)
for (alias = pmc_mdep_event_aliases; alias->pm_alias; alias++)
if (!strcasecmp(ctrspec, alias->pm_alias)) {
spec_copy = strdup(alias->pm_spec);
break;
}
if (spec_copy == NULL)
spec_copy = strdup(ctrspec);
r = spec_copy;
ctrname = strsep(&r, ",");
/*
* If a explicit class prefix was given by the user, restrict the
* search for the event to the specified PMC class.
*/
ev = NULL;
for (n = 0; n < PMC_CLASS_TABLE_SIZE; n++) {
pcd = pmc_class_table[n];
if (pcd && pmc_mdep_is_compatible_class(pcd->pm_evc_class) &&
strncasecmp(ctrname, pcd->pm_evc_name,
pcd->pm_evc_name_size) == 0) {
if ((ev = pmc_match_event_class(ctrname +
pcd->pm_evc_name_size, pcd)) == NULL) {
errno = EINVAL;
goto out;
}
break;
}
}
/*
* Otherwise, search for this event in all compatible PMC
* classes.
*/
for (n = 0; ev == NULL && n < PMC_CLASS_TABLE_SIZE; n++) {
pcd = pmc_class_table[n];
if (pcd && pmc_mdep_is_compatible_class(pcd->pm_evc_class))
ev = pmc_match_event_class(ctrname, pcd);
}
if (ev == NULL) {
errno = EINVAL;
goto out;
}
pmc_config.pm_ev = ev->pm_ev_code;
pmc_config.pm_class = pcd->pm_evc_class;
if (pcd->pm_evc_allocate_pmc(ev->pm_ev_code, r, &pmc_config) < 0) {
errno = EINVAL;
goto out;
}
if (PMC_CALL(PMCALLOCATE, &pmc_config) < 0)
goto out;
*pmcid = pmc_config.pm_pmcid;
retval = 0;
out:
if (spec_copy)
free(spec_copy);
return (retval);
}
int
pmc_attach(pmc_id_t pmc, pid_t pid)
{
struct pmc_op_pmcattach pmc_attach_args;
pmc_attach_args.pm_pmc = pmc;
pmc_attach_args.pm_pid = pid;
return (PMC_CALL(PMCATTACH, &pmc_attach_args));
}
int
pmc_capabilities(pmc_id_t pmcid, uint32_t *caps)
{
unsigned int i;
enum pmc_class cl;
cl = PMC_ID_TO_CLASS(pmcid);
for (i = 0; i < cpu_info.pm_nclass; i++)
if (cpu_info.pm_classes[i].pm_class == cl) {
*caps = cpu_info.pm_classes[i].pm_caps;
return (0);
}
errno = EINVAL;
return (-1);
}
int
pmc_configure_logfile(int fd)
{
struct pmc_op_configurelog cla;
cla.pm_logfd = fd;
if (PMC_CALL(CONFIGURELOG, &cla) < 0)
return (-1);
return (0);
}
int
pmc_cpuinfo(const struct pmc_cpuinfo **pci)
{
if (pmc_syscall == -1) {
errno = ENXIO;
return (-1);
}
*pci = &cpu_info;
return (0);
}
int
pmc_detach(pmc_id_t pmc, pid_t pid)
{
struct pmc_op_pmcattach pmc_detach_args;
pmc_detach_args.pm_pmc = pmc;
pmc_detach_args.pm_pid = pid;
return (PMC_CALL(PMCDETACH, &pmc_detach_args));
}
int
pmc_disable(int cpu, int pmc)
{
struct pmc_op_pmcadmin ssa;
ssa.pm_cpu = cpu;
ssa.pm_pmc = pmc;
ssa.pm_state = PMC_STATE_DISABLED;
return (PMC_CALL(PMCADMIN, &ssa));
}
int
pmc_enable(int cpu, int pmc)
{
struct pmc_op_pmcadmin ssa;
ssa.pm_cpu = cpu;
ssa.pm_pmc = pmc;
ssa.pm_state = PMC_STATE_FREE;
return (PMC_CALL(PMCADMIN, &ssa));
}
/*
* Return a list of events known to a given PMC class. 'cl' is the
* PMC class identifier, 'eventnames' is the returned list of 'const
* char *' pointers pointing to the names of the events. 'nevents' is
* the number of event name pointers returned.
*
* The space for 'eventnames' is allocated using malloc(3). The caller
* is responsible for freeing this space when done.
*/
int
pmc_event_names_of_class(enum pmc_class cl, const char ***eventnames,
int *nevents)
{
int count;
const char **names;
const struct pmc_event_descr *ev;
switch (cl)
{
case PMC_CLASS_IAF:
ev = iaf_event_table;
count = PMC_EVENT_TABLE_SIZE(iaf);
break;
case PMC_CLASS_TSC:
ev = tsc_event_table;
count = PMC_EVENT_TABLE_SIZE(tsc);
break;
case PMC_CLASS_K8:
ev = k8_event_table;
count = PMC_EVENT_TABLE_SIZE(k8);
break;
case PMC_CLASS_XSCALE:
ev = xscale_event_table;
count = PMC_EVENT_TABLE_SIZE(xscale);
break;
case PMC_CLASS_ARMV7:
switch (cpu_info.pm_cputype) {
default:
case PMC_CPU_ARMV7_CORTEX_A8:
ev = cortex_a8_event_table;
count = PMC_EVENT_TABLE_SIZE(cortex_a8);
break;
case PMC_CPU_ARMV7_CORTEX_A9:
ev = cortex_a9_event_table;
count = PMC_EVENT_TABLE_SIZE(cortex_a9);
break;
}
break;
case PMC_CLASS_ARMV8:
switch (cpu_info.pm_cputype) {
default:
case PMC_CPU_ARMV8_CORTEX_A53:
ev = cortex_a53_event_table;
count = PMC_EVENT_TABLE_SIZE(cortex_a53);
break;
case PMC_CPU_ARMV8_CORTEX_A57:
ev = cortex_a57_event_table;
count = PMC_EVENT_TABLE_SIZE(cortex_a57);
break;
}
break;
case PMC_CLASS_BERI:
ev = beri_event_table;
count = PMC_EVENT_TABLE_SIZE(beri);
break;
case PMC_CLASS_MIPS24K:
ev = mips24k_event_table;
count = PMC_EVENT_TABLE_SIZE(mips24k);
break;
case PMC_CLASS_MIPS74K:
ev = mips74k_event_table;
count = PMC_EVENT_TABLE_SIZE(mips74k);
break;
case PMC_CLASS_OCTEON:
ev = octeon_event_table;
count = PMC_EVENT_TABLE_SIZE(octeon);
break;
case PMC_CLASS_PPC7450:
ev = ppc7450_event_table;
count = PMC_EVENT_TABLE_SIZE(ppc7450);
break;
case PMC_CLASS_PPC970:
ev = ppc970_event_table;
count = PMC_EVENT_TABLE_SIZE(ppc970);
break;
case PMC_CLASS_E500:
ev = e500_event_table;
count = PMC_EVENT_TABLE_SIZE(e500);
break;
case PMC_CLASS_SOFT:
ev = soft_event_table;
count = soft_event_info.pm_nevent;
break;
default:
errno = EINVAL;
return (-1);
}
if ((names = malloc(count * sizeof(const char *))) == NULL)
return (-1);
*eventnames = names;
*nevents = count;
for (;count--; ev++, names++)
*names = ev->pm_ev_name;
return (0);
}
int
pmc_flush_logfile(void)
{
return (PMC_CALL(FLUSHLOG,0));
}
int
pmc_close_logfile(void)
{
return (PMC_CALL(CLOSELOG,0));
}
int
pmc_get_driver_stats(struct pmc_driverstats *ds)
{
struct pmc_op_getdriverstats gms;
if (PMC_CALL(GETDRIVERSTATS, &gms) < 0)
return (-1);
/* copy out fields in the current userland<->library interface */
ds->pm_intr_ignored = gms.pm_intr_ignored;
ds->pm_intr_processed = gms.pm_intr_processed;
ds->pm_intr_bufferfull = gms.pm_intr_bufferfull;
ds->pm_syscalls = gms.pm_syscalls;
ds->pm_syscall_errors = gms.pm_syscall_errors;
ds->pm_buffer_requests = gms.pm_buffer_requests;
ds->pm_buffer_requests_failed = gms.pm_buffer_requests_failed;
ds->pm_log_sweeps = gms.pm_log_sweeps;
return (0);
}
int
pmc_get_msr(pmc_id_t pmc, uint32_t *msr)
{
struct pmc_op_getmsr gm;
gm.pm_pmcid = pmc;
if (PMC_CALL(PMCGETMSR, &gm) < 0)
return (-1);
*msr = gm.pm_msr;
return (0);
}
int
pmc_init(void)
{
int error, pmc_mod_id;
unsigned int n;
uint32_t abi_version;
struct module_stat pmc_modstat;
struct pmc_op_getcpuinfo op_cpu_info;
#if defined(__amd64__) || defined(__i386__)
int cpu_has_iaf_counters;
unsigned int t;
#endif
if (pmc_syscall != -1) /* already inited */
return (0);
/* retrieve the system call number from the KLD */
if ((pmc_mod_id = modfind(PMC_MODULE_NAME)) < 0)
return (-1);
pmc_modstat.version = sizeof(struct module_stat);
if ((error = modstat(pmc_mod_id, &pmc_modstat)) < 0)
return (-1);
pmc_syscall = pmc_modstat.data.intval;
/* check the kernel module's ABI against our compiled-in version */
abi_version = PMC_VERSION;
if (PMC_CALL(GETMODULEVERSION, &abi_version) < 0)
return (pmc_syscall = -1);
/* ignore patch & minor numbers for the comparison */
if ((abi_version & 0xFF000000) != (PMC_VERSION & 0xFF000000)) {
errno = EPROGMISMATCH;
return (pmc_syscall = -1);
}
bzero(&op_cpu_info, sizeof(op_cpu_info));
if (PMC_CALL(GETCPUINFO, &op_cpu_info) < 0)
return (pmc_syscall = -1);
cpu_info.pm_cputype = op_cpu_info.pm_cputype;
cpu_info.pm_ncpu = op_cpu_info.pm_ncpu;
cpu_info.pm_npmc = op_cpu_info.pm_npmc;
cpu_info.pm_nclass = op_cpu_info.pm_nclass;
for (n = 0; n < op_cpu_info.pm_nclass; n++)
memcpy(&cpu_info.pm_classes[n], &op_cpu_info.pm_classes[n],
sizeof(cpu_info.pm_classes[n]));
pmc_class_table = malloc(PMC_CLASS_TABLE_SIZE *
sizeof(struct pmc_class_descr *));
if (pmc_class_table == NULL)
return (-1);
for (n = 0; n < PMC_CLASS_TABLE_SIZE; n++)
pmc_class_table[n] = NULL;
/*
* Get soft events list.
*/
soft_event_info.pm_class = PMC_CLASS_SOFT;
if (PMC_CALL(GETDYNEVENTINFO, &soft_event_info) < 0)
return (pmc_syscall = -1);
/* Map soft events to static list. */
for (n = 0; n < soft_event_info.pm_nevent; n++) {
soft_event_table[n].pm_ev_name =
soft_event_info.pm_events[n].pm_ev_name;
soft_event_table[n].pm_ev_code =
soft_event_info.pm_events[n].pm_ev_code;
}
soft_class_table_descr.pm_evc_event_table_size = \
soft_event_info.pm_nevent;
soft_class_table_descr.pm_evc_event_table = \
soft_event_table;
/*
* Fill in the class table.
*/
n = 0;
/* Fill soft events information. */
pmc_class_table[n++] = &soft_class_table_descr;
#if defined(__amd64__) || defined(__i386__)
if (cpu_info.pm_cputype != PMC_CPU_GENERIC)
pmc_class_table[n++] = &tsc_class_table_descr;
/*
* Check if this CPU has fixed function counters.
*/
cpu_has_iaf_counters = 0;
for (t = 0; t < cpu_info.pm_nclass; t++)
if (cpu_info.pm_classes[t].pm_class == PMC_CLASS_IAF &&
cpu_info.pm_classes[t].pm_num > 0)
cpu_has_iaf_counters = 1;
#endif
#define PMC_MDEP_INIT(C) do { \
pmc_mdep_event_aliases = C##_aliases; \
pmc_mdep_class_list = C##_pmc_classes; \
pmc_mdep_class_list_size = \
PMC_TABLE_SIZE(C##_pmc_classes); \
} while (0)
#define PMC_MDEP_INIT_INTEL_V2(C) do { \
PMC_MDEP_INIT(C); \
pmc_class_table[n++] = &iaf_class_table_descr; \
if (!cpu_has_iaf_counters) \
pmc_mdep_event_aliases = \
C##_aliases_without_iaf; \
pmc_class_table[n] = &C##_class_table_descr; \
} while (0)
/* Configure the event name parser. */
switch (cpu_info.pm_cputype) {
#if defined(__amd64__) || defined(__i386__)
case PMC_CPU_AMD_K8:
PMC_MDEP_INIT(k8);
pmc_class_table[n] = &k8_class_table_descr;
break;
#endif
case PMC_CPU_GENERIC:
PMC_MDEP_INIT(generic);
break;
#if defined(__arm__)
#if defined(__XSCALE__)
case PMC_CPU_INTEL_XSCALE:
PMC_MDEP_INIT(xscale);
pmc_class_table[n] = &xscale_class_table_descr;
break;
#endif
case PMC_CPU_ARMV7_CORTEX_A8:
PMC_MDEP_INIT(cortex_a8);
pmc_class_table[n] = &cortex_a8_class_table_descr;
break;
case PMC_CPU_ARMV7_CORTEX_A9:
PMC_MDEP_INIT(cortex_a9);
pmc_class_table[n] = &cortex_a9_class_table_descr;
break;
#endif
#if defined(__aarch64__)
case PMC_CPU_ARMV8_CORTEX_A53:
PMC_MDEP_INIT(cortex_a53);
pmc_class_table[n] = &cortex_a53_class_table_descr;
break;
case PMC_CPU_ARMV8_CORTEX_A57:
PMC_MDEP_INIT(cortex_a57);
pmc_class_table[n] = &cortex_a57_class_table_descr;
break;
#endif
#if defined(__mips__)
case PMC_CPU_MIPS_BERI:
PMC_MDEP_INIT(beri);
pmc_class_table[n] = &beri_class_table_descr;
break;
case PMC_CPU_MIPS_24K:
PMC_MDEP_INIT(mips24k);
pmc_class_table[n] = &mips24k_class_table_descr;
break;
case PMC_CPU_MIPS_74K:
PMC_MDEP_INIT(mips74k);
pmc_class_table[n] = &mips74k_class_table_descr;
break;
case PMC_CPU_MIPS_OCTEON:
PMC_MDEP_INIT(octeon);
pmc_class_table[n] = &octeon_class_table_descr;
break;
#endif /* __mips__ */
#if defined(__powerpc__)
case PMC_CPU_PPC_7450:
PMC_MDEP_INIT(ppc7450);
pmc_class_table[n] = &ppc7450_class_table_descr;
break;
case PMC_CPU_PPC_970:
PMC_MDEP_INIT(ppc970);
pmc_class_table[n] = &ppc970_class_table_descr;
break;
case PMC_CPU_PPC_E500:
PMC_MDEP_INIT(e500);
pmc_class_table[n] = &e500_class_table_descr;
break;
#endif
default:
/*
* Some kind of CPU this version of the library knows nothing
* about. This shouldn't happen since the abi version check
* should have caught this.
*/
#if defined(__amd64__) || defined(__i386__)
break;
#endif
errno = ENXIO;
return (pmc_syscall = -1);
}
return (0);
}
const char *
pmc_name_of_capability(enum pmc_caps cap)
{
int i;
/*
* 'cap' should have a single bit set and should be in
* range.
*/
if ((cap & (cap - 1)) || cap < PMC_CAP_FIRST ||
cap > PMC_CAP_LAST) {
errno = EINVAL;
return (NULL);
}
i = ffs(cap);
return (pmc_capability_names[i - 1]);
}
const char *
pmc_name_of_class(enum pmc_class pc)
{
size_t n;
for (n = 0; n < PMC_TABLE_SIZE(pmc_class_names); n++)
if (pc == pmc_class_names[n].pm_class)
return (pmc_class_names[n].pm_name);
errno = EINVAL;
return (NULL);
}
const char *
pmc_name_of_cputype(enum pmc_cputype cp)
{
size_t n;
for (n = 0; n < PMC_TABLE_SIZE(pmc_cputype_names); n++)
if (cp == pmc_cputype_names[n].pm_cputype)
return (pmc_cputype_names[n].pm_name);
errno = EINVAL;
return (NULL);
}
const char *
pmc_name_of_disposition(enum pmc_disp pd)
{
if ((int) pd >= PMC_DISP_FIRST &&
pd <= PMC_DISP_LAST)
return (pmc_disposition_names[pd]);
errno = EINVAL;
return (NULL);
}
const char *
_pmc_name_of_event(enum pmc_event pe, enum pmc_cputype cpu)
{
const struct pmc_event_descr *ev, *evfence;
ev = evfence = NULL;
if (pe >= PMC_EV_K8_FIRST && pe <= PMC_EV_K8_LAST) {
ev = k8_event_table;
evfence = k8_event_table + PMC_EVENT_TABLE_SIZE(k8);
} else if (pe >= PMC_EV_XSCALE_FIRST && pe <= PMC_EV_XSCALE_LAST) {
ev = xscale_event_table;
evfence = xscale_event_table + PMC_EVENT_TABLE_SIZE(xscale);
} else if (pe >= PMC_EV_ARMV7_FIRST && pe <= PMC_EV_ARMV7_LAST) {
switch (cpu) {
case PMC_CPU_ARMV7_CORTEX_A8:
ev = cortex_a8_event_table;
evfence = cortex_a8_event_table + PMC_EVENT_TABLE_SIZE(cortex_a8);
break;
case PMC_CPU_ARMV7_CORTEX_A9:
ev = cortex_a9_event_table;
evfence = cortex_a9_event_table + PMC_EVENT_TABLE_SIZE(cortex_a9);
break;
default: /* Unknown CPU type. */
break;
}
} else if (pe >= PMC_EV_ARMV8_FIRST && pe <= PMC_EV_ARMV8_LAST) {
switch (cpu) {
case PMC_CPU_ARMV8_CORTEX_A53:
ev = cortex_a53_event_table;
evfence = cortex_a53_event_table + PMC_EVENT_TABLE_SIZE(cortex_a53);
break;
case PMC_CPU_ARMV8_CORTEX_A57:
ev = cortex_a57_event_table;
evfence = cortex_a57_event_table + PMC_EVENT_TABLE_SIZE(cortex_a57);
break;
default: /* Unknown CPU type. */
break;
}
} else if (pe >= PMC_EV_BERI_FIRST && pe <= PMC_EV_BERI_LAST) {
ev = beri_event_table;
evfence = beri_event_table + PMC_EVENT_TABLE_SIZE(beri);
} else if (pe >= PMC_EV_MIPS24K_FIRST && pe <= PMC_EV_MIPS24K_LAST) {
ev = mips24k_event_table;
evfence = mips24k_event_table + PMC_EVENT_TABLE_SIZE(mips24k);
} else if (pe >= PMC_EV_MIPS74K_FIRST && pe <= PMC_EV_MIPS74K_LAST) {
ev = mips74k_event_table;
evfence = mips74k_event_table + PMC_EVENT_TABLE_SIZE(mips74k);
} else if (pe >= PMC_EV_OCTEON_FIRST && pe <= PMC_EV_OCTEON_LAST) {
ev = octeon_event_table;
evfence = octeon_event_table + PMC_EVENT_TABLE_SIZE(octeon);
} else if (pe >= PMC_EV_PPC7450_FIRST && pe <= PMC_EV_PPC7450_LAST) {
ev = ppc7450_event_table;
evfence = ppc7450_event_table + PMC_EVENT_TABLE_SIZE(ppc7450);
} else if (pe >= PMC_EV_PPC970_FIRST && pe <= PMC_EV_PPC970_LAST) {
ev = ppc970_event_table;
evfence = ppc970_event_table + PMC_EVENT_TABLE_SIZE(ppc970);
} else if (pe >= PMC_EV_E500_FIRST && pe <= PMC_EV_E500_LAST) {
ev = e500_event_table;
evfence = e500_event_table + PMC_EVENT_TABLE_SIZE(e500);
} else if (pe == PMC_EV_TSC_TSC) {
ev = tsc_event_table;
evfence = tsc_event_table + PMC_EVENT_TABLE_SIZE(tsc);
} else if ((int)pe >= PMC_EV_SOFT_FIRST && (int)pe <= PMC_EV_SOFT_LAST) {
ev = soft_event_table;
evfence = soft_event_table + soft_event_info.pm_nevent;
}
for (; ev != evfence; ev++)
if (pe == ev->pm_ev_code)
return (ev->pm_ev_name);
return (NULL);
}
const char *
pmc_name_of_event(enum pmc_event pe)
{
const char *n;
if ((n = _pmc_name_of_event(pe, cpu_info.pm_cputype)) != NULL)
return (n);
errno = EINVAL;
return (NULL);
}
const char *
pmc_name_of_mode(enum pmc_mode pm)
{
if ((int) pm >= PMC_MODE_FIRST &&
pm <= PMC_MODE_LAST)
return (pmc_mode_names[pm]);
errno = EINVAL;
return (NULL);
}
const char *
pmc_name_of_state(enum pmc_state ps)
{
if ((int) ps >= PMC_STATE_FIRST &&
ps <= PMC_STATE_LAST)
return (pmc_state_names[ps]);
errno = EINVAL;
return (NULL);
}
int
pmc_ncpu(void)
{
if (pmc_syscall == -1) {
errno = ENXIO;
return (-1);
}
return (cpu_info.pm_ncpu);
}
int
pmc_npmc(int cpu)
{
if (pmc_syscall == -1) {
errno = ENXIO;
return (-1);
}
if (cpu < 0 || cpu >= (int) cpu_info.pm_ncpu) {
errno = EINVAL;
return (-1);
}
return (cpu_info.pm_npmc);
}
int
pmc_pmcinfo(int cpu, struct pmc_pmcinfo **ppmci)
{
int nbytes, npmc;
struct pmc_op_getpmcinfo *pmci;
if ((npmc = pmc_npmc(cpu)) < 0)
return (-1);
nbytes = sizeof(struct pmc_op_getpmcinfo) +
npmc * sizeof(struct pmc_info);
if ((pmci = calloc(1, nbytes)) == NULL)
return (-1);
pmci->pm_cpu = cpu;
if (PMC_CALL(GETPMCINFO, pmci) < 0) {
free(pmci);
return (-1);
}
/* kernel<->library, library<->userland interfaces are identical */
*ppmci = (struct pmc_pmcinfo *) pmci;
return (0);
}
int
pmc_read(pmc_id_t pmc, pmc_value_t *value)
{
struct pmc_op_pmcrw pmc_read_op;
pmc_read_op.pm_pmcid = pmc;
pmc_read_op.pm_flags = PMC_F_OLDVALUE;
pmc_read_op.pm_value = -1;
if (PMC_CALL(PMCRW, &pmc_read_op) < 0)
return (-1);
*value = pmc_read_op.pm_value;
return (0);
}
int
pmc_release(pmc_id_t pmc)
{
struct pmc_op_simple pmc_release_args;
pmc_release_args.pm_pmcid = pmc;
return (PMC_CALL(PMCRELEASE, &pmc_release_args));
}
int
pmc_rw(pmc_id_t pmc, pmc_value_t newvalue, pmc_value_t *oldvaluep)
{
struct pmc_op_pmcrw pmc_rw_op;
pmc_rw_op.pm_pmcid = pmc;
pmc_rw_op.pm_flags = PMC_F_NEWVALUE | PMC_F_OLDVALUE;
pmc_rw_op.pm_value = newvalue;
if (PMC_CALL(PMCRW, &pmc_rw_op) < 0)
return (-1);
*oldvaluep = pmc_rw_op.pm_value;
return (0);
}
int
pmc_set(pmc_id_t pmc, pmc_value_t value)
{
struct pmc_op_pmcsetcount sc;
sc.pm_pmcid = pmc;
sc.pm_count = value;
if (PMC_CALL(PMCSETCOUNT, &sc) < 0)
return (-1);
return (0);
}
int
pmc_start(pmc_id_t pmc)
{
struct pmc_op_simple pmc_start_args;
pmc_start_args.pm_pmcid = pmc;
return (PMC_CALL(PMCSTART, &pmc_start_args));
}
int
pmc_stop(pmc_id_t pmc)
{
struct pmc_op_simple pmc_stop_args;
pmc_stop_args.pm_pmcid = pmc;
return (PMC_CALL(PMCSTOP, &pmc_stop_args));
}
int
pmc_width(pmc_id_t pmcid, uint32_t *width)
{
unsigned int i;
enum pmc_class cl;
cl = PMC_ID_TO_CLASS(pmcid);
for (i = 0; i < cpu_info.pm_nclass; i++)
if (cpu_info.pm_classes[i].pm_class == cl) {
*width = cpu_info.pm_classes[i].pm_width;
return (0);
}
errno = EINVAL;
return (-1);
}
int
pmc_write(pmc_id_t pmc, pmc_value_t value)
{
struct pmc_op_pmcrw pmc_write_op;
pmc_write_op.pm_pmcid = pmc;
pmc_write_op.pm_flags = PMC_F_NEWVALUE;
pmc_write_op.pm_value = value;
return (PMC_CALL(PMCRW, &pmc_write_op));
}
int
pmc_writelog(uint32_t userdata)
{
struct pmc_op_writelog wl;
wl.pm_userdata = userdata;
return (PMC_CALL(WRITELOG, &wl));
}