Merge libcxxrt master fd484be8d1e94a1fcf6bc5c67e5c07b65ada19b6

[FreeBSD/FreeBSD.git] / lib / libpmc / libpmc.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__)
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
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(armv7, ARMV7);
PMC_CLASSDEP_TABLE(armv8, ARMV8);
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 },

/*
 * TODO: Factor out the __PMC_EV_ARMV7/8 list into a single separate table
 * rather than duplicating for each core.
 */

static const struct pmc_event_descr cortex_a8_event_table[] = 
{
        __PMC_EV_ALIAS_ARMV7_CORTEX_A8()
        __PMC_EV_ARMV7()
};

static const struct pmc_event_descr cortex_a9_event_table[] = 
{
        __PMC_EV_ALIAS_ARMV7_CORTEX_A9()
        __PMC_EV_ARMV7()
};

static const struct pmc_event_descr cortex_a53_event_table[] = 
{
        __PMC_EV_ALIAS_ARMV8_CORTEX_A53()
        __PMC_EV_ARMV8()
};

static const struct pmc_event_descr cortex_a57_event_table[] = 
{
        __PMC_EV_ALIAS_ARMV8_CORTEX_A57()
        __PMC_EV_ARMV8()
};

static const struct pmc_event_descr cortex_a76_event_table[] =
{
        __PMC_EV_ALIAS_ARMV8_CORTEX_A76()
        __PMC_EV_ARMV8()
};

static const struct pmc_event_descr tsc_event_table[] =
{
        __PMC_EV_ALIAS_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__)
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);
PMC_CLASS_TABLE_DESC(cortex_a76, ARMV8, cortex_a76, arm64);
#endif
#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

/*
 * 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__)
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 struct pmc_event_alias cortex_a76_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(__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);
}

/*
 * 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;

        /*
         * Try to pull the raw event ID directly from the pmu-events table. If
         * this is unsupported on the platform, or the event is not found,
         * continue with searching the regular event tables.
         */
        r = spec_copy = strdup(ctrspec);
        ctrname = strsep(&r, ",");
        if (pmc_pmu_enabled()) {
                if (pmc_pmu_pmcallocate(ctrname, &pmc_config) == 0)
                        goto found;

                /* Otherwise, reset any changes */
                pmc_config.pm_ev = 0;
                pmc_config.pm_caps = 0;
                pmc_config.pm_class = 0;
        }
        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 != NULL && 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 != NULL)
                        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;
        }

found:
        if (PMC_CALL(PMCALLOCATE, &pmc_config) == 0) {
                *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_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;
                case PMC_CPU_ARMV8_CORTEX_A76:
                        ev = cortex_a76_event_table;
                        count = PMC_EVENT_TABLE_SIZE(cortex_a76);
                        break;
                }
                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 (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;
#endif

#define PMC_MDEP_INIT(C) pmc_mdep_event_aliases = C##_aliases

        /* 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__)
        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;
        case PMC_CPU_ARMV8_CORTEX_A76:
                PMC_MDEP_INIT(cortex_a76);
                pmc_class_table[n] = &cortex_a76_class_table_descr;
                break;
#endif
#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__) || defined(__powerpc64__)
                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_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;
                case PMC_CPU_ARMV8_CORTEX_A76:
                        ev = cortex_a76_event_table;
                        evfence = cortex_a76_event_table + PMC_EVENT_TABLE_SIZE(cortex_a76);
                        break;
                default:        /* Unknown CPU type. */
                        break;
                }
        } 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));
}