#include <mach/mach_types.h>
#include <machine/machine_routines.h>
#include <kern/processor.h>
#include <kern/kalloc.h>
#include <sys/errno.h>
#include <sys/vm.h>
#include <kperf/buffer.h>
#include <kern/thread.h>
#if defined(__arm64__) || defined(__arm__)
#include <arm/cpu_data_internal.h>
#endif
#include <kern/kpc.h>
#include <kperf/kperf.h>
#include <kperf/sample.h>
#include <kperf/context.h>
#include <kperf/action.h>
#include <chud/chud_xnu.h>
uint32_t kpc_actionid[KPC_MAX_COUNTERS];
#define COUNTERBUF_SIZE_PER_CPU (KPC_MAX_COUNTERS * sizeof(uint64_t))
#define COUNTERBUF_SIZE (machine_info.logical_cpu_max * \
COUNTERBUF_SIZE_PER_CPU)
static lck_grp_attr_t *kpc_config_lckgrp_attr = NULL;
static lck_grp_t *kpc_config_lckgrp = NULL;
static lck_mtx_t kpc_config_lock;
static boolean_t force_all_ctrs = FALSE;
static kpc_pm_handler_t kpc_pm_handler;
static boolean_t kpc_pm_has_custom_config;
static uint64_t kpc_pm_pmc_mask;
#if MACH_ASSERT
static bool kpc_calling_pm = false;
#endif
boolean_t kpc_context_switch_active = FALSE;
void kpc_common_init(void);
void
kpc_common_init(void)
{
kpc_config_lckgrp_attr = lck_grp_attr_alloc_init();
kpc_config_lckgrp = lck_grp_alloc_init("kpc", kpc_config_lckgrp_attr);
lck_mtx_init(&kpc_config_lock, kpc_config_lckgrp, LCK_ATTR_NULL);
}
boolean_t
kpc_register_cpu(struct cpu_data *cpu_data)
{
assert(cpu_data);
assert(cpu_data->cpu_kpc_buf[0] == NULL);
assert(cpu_data->cpu_kpc_buf[1] == NULL);
assert(cpu_data->cpu_kpc_shadow == NULL);
assert(cpu_data->cpu_kpc_reload == NULL);
if ((cpu_data->cpu_kpc_buf[0] = kalloc(COUNTERBUF_SIZE_PER_CPU)) == NULL)
goto error;
if ((cpu_data->cpu_kpc_buf[1] = kalloc(COUNTERBUF_SIZE_PER_CPU)) == NULL)
goto error;
if ((cpu_data->cpu_kpc_shadow = kalloc(COUNTERBUF_SIZE_PER_CPU)) == NULL)
goto error;
if ((cpu_data->cpu_kpc_reload = kalloc(COUNTERBUF_SIZE_PER_CPU)) == NULL)
goto error;
memset(cpu_data->cpu_kpc_buf[0], 0, COUNTERBUF_SIZE_PER_CPU);
memset(cpu_data->cpu_kpc_buf[1], 0, COUNTERBUF_SIZE_PER_CPU);
memset(cpu_data->cpu_kpc_shadow, 0, COUNTERBUF_SIZE_PER_CPU);
memset(cpu_data->cpu_kpc_reload, 0, COUNTERBUF_SIZE_PER_CPU);
return TRUE;
error:
kpc_unregister_cpu(cpu_data);
return FALSE;
}
void
kpc_unregister_cpu(struct cpu_data *cpu_data)
{
assert(cpu_data);
if (cpu_data->cpu_kpc_buf[0] != NULL) {
kfree(cpu_data->cpu_kpc_buf[0], COUNTERBUF_SIZE_PER_CPU);
cpu_data->cpu_kpc_buf[0] = NULL;
}
if (cpu_data->cpu_kpc_buf[1] != NULL) {
kfree(cpu_data->cpu_kpc_buf[1], COUNTERBUF_SIZE_PER_CPU);
cpu_data->cpu_kpc_buf[1] = NULL;
}
if (cpu_data->cpu_kpc_shadow != NULL) {
kfree(cpu_data->cpu_kpc_shadow, COUNTERBUF_SIZE_PER_CPU);
cpu_data->cpu_kpc_shadow = NULL;
}
if (cpu_data->cpu_kpc_reload != NULL) {
kfree(cpu_data->cpu_kpc_reload, COUNTERBUF_SIZE_PER_CPU);
cpu_data->cpu_kpc_reload = NULL;
}
}
static void
kpc_task_set_forced_all_ctrs(task_t task, boolean_t state)
{
assert(task);
task_lock(task);
if (state)
task->t_chud |= TASK_KPC_FORCED_ALL_CTRS;
else
task->t_chud &= ~TASK_KPC_FORCED_ALL_CTRS;
task_unlock(task);
}
static boolean_t
kpc_task_get_forced_all_ctrs(task_t task)
{
assert(task);
return task->t_chud & TASK_KPC_FORCED_ALL_CTRS ? TRUE : FALSE;
}
int
kpc_force_all_ctrs(task_t task, int val)
{
boolean_t new_state = val ? TRUE : FALSE;
boolean_t old_state = kpc_get_force_all_ctrs();
if (kpc_get_force_all_ctrs() && !kpc_task_get_forced_all_ctrs(task))
return EACCES;
if (old_state == new_state)
return 0;
if (kpc_pm_handler) {
#if MACH_ASSERT
kpc_calling_pm = true;
#endif
kpc_pm_handler( new_state ? FALSE : TRUE );
#if MACH_ASSERT
kpc_calling_pm = false;
#endif
}
if (force_all_ctrs != new_state) {
force_all_ctrs = new_state;
}
kpc_task_set_forced_all_ctrs(task, new_state);
return 0;
}
void
kpc_pm_acknowledge(boolean_t available_to_pm)
{
assert(force_all_ctrs == available_to_pm);
assert(kpc_calling_pm == true);
force_all_ctrs = available_to_pm ? FALSE : TRUE;
}
int
kpc_get_force_all_ctrs(void)
{
return force_all_ctrs;
}
boolean_t
kpc_multiple_clients(void)
{
return kpc_pm_handler != NULL;
}
boolean_t
kpc_controls_fixed_counters(void)
{
return !kpc_pm_handler || force_all_ctrs || !kpc_pm_has_custom_config;
}
boolean_t
kpc_controls_counter(uint32_t ctr)
{
uint64_t pmc_mask = 0ULL;
assert(ctr < (kpc_fixed_count() + kpc_configurable_count()));
if (ctr < kpc_fixed_count())
return kpc_controls_fixed_counters();
pmc_mask = (1ULL << (ctr - kpc_fixed_count()));
if ((pmc_mask & kpc_pm_pmc_mask) && kpc_pm_has_custom_config && !force_all_ctrs)
return FALSE;
return TRUE;
}
uint32_t
kpc_get_running(void)
{
uint64_t pmc_mask = 0;
uint32_t cur_state = 0;
if (kpc_is_running_fixed())
cur_state |= KPC_CLASS_FIXED_MASK;
pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_CONFIGURABLE_MASK);
if (kpc_is_running_configurable(pmc_mask))
cur_state |= KPC_CLASS_CONFIGURABLE_MASK;
pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_POWER_MASK);
if ((pmc_mask != 0) && kpc_is_running_configurable(pmc_mask))
cur_state |= KPC_CLASS_POWER_MASK;
return cur_state;
}
int
kpc_get_curcpu_counters(uint32_t classes, int *curcpu, uint64_t *buf)
{
int enabled=0, offset=0;
uint64_t pmc_mask = 0ULL;
assert(buf);
enabled = ml_set_interrupts_enabled(FALSE);
if (curcpu)
*curcpu = current_processor()->cpu_id;
if (classes & KPC_CLASS_FIXED_MASK) {
kpc_get_fixed_counters(&buf[offset]);
offset += kpc_get_counter_count(KPC_CLASS_FIXED_MASK);
}
if (classes & KPC_CLASS_CONFIGURABLE_MASK) {
pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_CONFIGURABLE_MASK);
kpc_get_configurable_counters(&buf[offset], pmc_mask);
offset += kpc_popcount(pmc_mask);
}
if (classes & KPC_CLASS_POWER_MASK) {
pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_POWER_MASK);
kpc_get_configurable_counters(&buf[offset], pmc_mask);
offset += kpc_popcount(pmc_mask);
}
ml_set_interrupts_enabled(enabled);
return offset;
}
int
kpc_get_cpu_counters(boolean_t all_cpus, uint32_t classes,
int *curcpu, uint64_t *buf)
{
assert(buf);
if (all_cpus)
return kpc_get_all_cpus_counters(classes, curcpu, buf);
else
return kpc_get_curcpu_counters(classes, curcpu, buf);
}
int
kpc_get_shadow_counters(boolean_t all_cpus, uint32_t classes,
int *curcpu, uint64_t *buf)
{
int curcpu_id = current_processor()->cpu_id;
uint32_t cfg_count = kpc_configurable_count(), offset = 0;
uint64_t pmc_mask = 0ULL;
boolean_t enabled;
assert(buf);
enabled = ml_set_interrupts_enabled(FALSE);
curcpu_id = current_processor()->cpu_id;
if (curcpu)
*curcpu = curcpu_id;
for (int cpu = 0; cpu < machine_info.logical_cpu_max; ++cpu) {
if (!all_cpus && (cpu != curcpu_id))
continue;
if (classes & KPC_CLASS_FIXED_MASK) {
uint32_t count = kpc_get_counter_count(KPC_CLASS_FIXED_MASK);
memcpy(&buf[offset], &FIXED_SHADOW_CPU(cpu, 0), count * sizeof(uint64_t));
offset += count;
}
if (classes & KPC_CLASS_CONFIGURABLE_MASK) {
pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_CONFIGURABLE_MASK);
for (uint32_t cfg_ctr = 0; cfg_ctr < cfg_count; ++cfg_ctr)
if ((1ULL << cfg_ctr) & pmc_mask)
buf[offset++] = CONFIGURABLE_SHADOW_CPU(cpu, cfg_ctr);
}
if (classes & KPC_CLASS_POWER_MASK) {
pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_POWER_MASK);
for (uint32_t cfg_ctr = 0; cfg_ctr < cfg_count; ++cfg_ctr)
if ((1ULL << cfg_ctr) & pmc_mask)
buf[offset++] = CONFIGURABLE_SHADOW_CPU(cpu, cfg_ctr);
}
}
ml_set_interrupts_enabled(enabled);
return offset;
}
uint32_t
kpc_get_counter_count(uint32_t classes)
{
uint32_t count = 0;
if (classes & KPC_CLASS_FIXED_MASK)
count += kpc_fixed_count();
if (classes & (KPC_CLASS_CONFIGURABLE_MASK | KPC_CLASS_POWER_MASK)) {
uint64_t pmc_msk = kpc_get_configurable_pmc_mask(classes);
uint32_t pmc_cnt = kpc_popcount(pmc_msk);
count += pmc_cnt;
}
return count;
}
uint32_t
kpc_get_config_count(uint32_t classes)
{
uint32_t count = 0;
if (classes & KPC_CLASS_FIXED_MASK)
count += kpc_fixed_config_count();
if (classes & (KPC_CLASS_CONFIGURABLE_MASK | KPC_CLASS_POWER_MASK)) {
uint64_t pmc_mask = kpc_get_configurable_pmc_mask(classes);
count += kpc_configurable_config_count(pmc_mask);
}
if ((classes & KPC_CLASS_RAWPMU_MASK) && !kpc_multiple_clients())
count += kpc_rawpmu_config_count();
return count;
}
int
kpc_get_config(uint32_t classes, kpc_config_t *current_config)
{
uint32_t count = 0;
assert(current_config);
if (classes & KPC_CLASS_FIXED_MASK) {
kpc_get_fixed_config(¤t_config[count]);
count += kpc_get_config_count(KPC_CLASS_FIXED_MASK);
}
if (classes & KPC_CLASS_CONFIGURABLE_MASK) {
uint64_t pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_CONFIGURABLE_MASK);
kpc_get_configurable_config(¤t_config[count], pmc_mask);
count += kpc_get_config_count(KPC_CLASS_CONFIGURABLE_MASK);
}
if (classes & KPC_CLASS_POWER_MASK) {
uint64_t pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_POWER_MASK);
kpc_get_configurable_config(¤t_config[count], pmc_mask);
count += kpc_get_config_count(KPC_CLASS_POWER_MASK);
}
if (classes & KPC_CLASS_RAWPMU_MASK)
{
if( kpc_multiple_clients() )
{
return EPERM;
}
kpc_get_rawpmu_config(¤t_config[count]);
count += kpc_get_config_count(KPC_CLASS_RAWPMU_MASK);
}
return 0;
}
int
kpc_set_config(uint32_t classes, kpc_config_t *configv)
{
int ret = 0;
struct kpc_config_remote mp_config = {
.classes = classes, .configv = configv,
.pmc_mask = kpc_get_configurable_pmc_mask(classes)
};
assert(configv);
if ((classes & KPC_CLASS_RAWPMU_MASK) && kpc_multiple_clients()) {
return EPERM;
}
if ((classes & (KPC_CLASS_CONFIGURABLE_MASK)) &&
(classes & (KPC_CLASS_POWER_MASK)))
{
return EPERM;
}
lck_mtx_lock(&kpc_config_lock);
if (classes & KPC_CLASS_POWER_MASK)
mp_config.classes |= KPC_CLASS_CONFIGURABLE_MASK;
ret = kpc_set_config_arch( &mp_config );
lck_mtx_unlock(&kpc_config_lock);
return ret;
}
uint64_t *
kpc_counterbuf_alloc(void)
{
uint64_t *buf = NULL;
buf = kalloc(COUNTERBUF_SIZE);
if (buf) {
bzero(buf, COUNTERBUF_SIZE);
}
return buf;
}
void
kpc_counterbuf_free(uint64_t *buf)
{
if (buf) {
kfree(buf, COUNTERBUF_SIZE);
}
}
void
kpc_sample_kperf(uint32_t actionid)
{
struct kperf_sample sbuf;
struct kperf_context ctx;
BUF_DATA(PERF_KPC_HNDLR | DBG_FUNC_START);
ctx.cur_pid = 0;
ctx.cur_thread = current_thread();
ctx.cur_pid = task_pid(current_task());
ctx.trigger_type = TRIGGER_TYPE_PMI;
ctx.trigger_id = 0;
int r = kperf_sample(&sbuf, &ctx, actionid, SAMPLE_FLAG_PEND_USER);
BUF_INFO(PERF_KPC_HNDLR | DBG_FUNC_END, r);
}
int
kpc_set_period(uint32_t classes, uint64_t *val)
{
struct kpc_config_remote mp_config = {
.classes = classes, .configv = val,
.pmc_mask = kpc_get_configurable_pmc_mask(classes)
};
assert(val);
if ((classes & (KPC_CLASS_CONFIGURABLE_MASK)) &&
(classes & (KPC_CLASS_POWER_MASK)))
{
return EPERM;
}
lck_mtx_lock(&kpc_config_lock);
#ifdef FIXED_COUNTER_SHADOW
if ((classes & KPC_CLASS_FIXED_MASK) && !kpc_controls_fixed_counters()) {
lck_mtx_unlock(&kpc_config_lock);
return EPERM;
}
# else
if (classes & KPC_CLASS_FIXED_MASK) {
lck_mtx_unlock(&kpc_config_lock);
return EINVAL;
}
#endif
if (classes & KPC_CLASS_POWER_MASK)
mp_config.classes |= KPC_CLASS_CONFIGURABLE_MASK;
kprintf("setting period %u\n", classes);
kpc_set_period_arch( &mp_config );
lck_mtx_unlock(&kpc_config_lock);
return 0;
}
int
kpc_get_period(uint32_t classes, uint64_t *val)
{
uint32_t count = 0 ;
uint64_t pmc_mask = 0ULL;
assert(val);
lck_mtx_lock(&kpc_config_lock);
if (classes & KPC_CLASS_FIXED_MASK) {
count = kpc_get_counter_count(KPC_CLASS_FIXED_MASK);
for (uint32_t i = 0; i < count; ++i)
*val++ = kpc_fixed_max() - FIXED_RELOAD(i);
}
if (classes & KPC_CLASS_CONFIGURABLE_MASK) {
pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_CONFIGURABLE_MASK);
count = kpc_configurable_count();
for (uint32_t i = 0; i < count; ++i)
if ((1ULL << i) & pmc_mask)
*val++ = kpc_configurable_max() - CONFIGURABLE_RELOAD(i);
}
if (classes & KPC_CLASS_POWER_MASK) {
pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_POWER_MASK);
count = kpc_configurable_count();
for (uint32_t i = 0; i < count; ++i)
if ((1ULL << i) & pmc_mask)
*val++ = kpc_configurable_max() - CONFIGURABLE_RELOAD(i);
}
lck_mtx_unlock(&kpc_config_lock);
return 0;
}
int
kpc_set_actionid(uint32_t classes, uint32_t *val)
{
uint32_t count = 0;
uint64_t pmc_mask = 0ULL;
assert(val);
lck_mtx_lock(&kpc_config_lock);
if (classes & KPC_CLASS_FIXED_MASK) {
count = kpc_get_counter_count(KPC_CLASS_FIXED_MASK);
memcpy(&FIXED_ACTIONID(0), val, count*sizeof(uint32_t));
val += count;
}
if (classes & KPC_CLASS_CONFIGURABLE_MASK) {
pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_CONFIGURABLE_MASK);
count = kpc_configurable_count();
for (uint32_t i = 0; i < count; ++i)
if ((1ULL << i) & pmc_mask)
CONFIGURABLE_ACTIONID(i) = *val++;
}
if (classes & KPC_CLASS_POWER_MASK) {
pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_POWER_MASK);
count = kpc_configurable_count();
for (uint32_t i = 0; i < count; ++i)
if ((1ULL << i) & pmc_mask)
CONFIGURABLE_ACTIONID(i) = *val++;
}
lck_mtx_unlock(&kpc_config_lock);
return 0;
}
int kpc_get_actionid(uint32_t classes, uint32_t *val)
{
uint32_t count = 0;
uint64_t pmc_mask = 0ULL;
assert(val);
lck_mtx_lock(&kpc_config_lock);
if (classes & KPC_CLASS_FIXED_MASK) {
count = kpc_get_counter_count(KPC_CLASS_FIXED_MASK);
memcpy(val, &FIXED_ACTIONID(0), count*sizeof(uint32_t));
val += count;
}
if (classes & KPC_CLASS_CONFIGURABLE_MASK) {
pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_CONFIGURABLE_MASK);
count = kpc_configurable_count();
for (uint32_t i = 0; i < count; ++i)
if ((1ULL << i) & pmc_mask)
*val++ = CONFIGURABLE_ACTIONID(i);
}
if (classes & KPC_CLASS_POWER_MASK) {
pmc_mask = kpc_get_configurable_pmc_mask(KPC_CLASS_POWER_MASK);
count = kpc_configurable_count();
for (uint32_t i = 0; i < count; ++i)
if ((1ULL << i) & pmc_mask)
*val++ = CONFIGURABLE_ACTIONID(i);
}
lck_mtx_unlock(&kpc_config_lock);
return 0;
}
int
kpc_set_running(uint32_t classes)
{
uint32_t all_cfg_classes = KPC_CLASS_CONFIGURABLE_MASK | KPC_CLASS_POWER_MASK;
struct kpc_running_remote mp_config = {
.classes = classes, .cfg_target_mask= 0ULL, .cfg_state_mask = 0ULL
};
mp_config.cfg_target_mask = kpc_get_configurable_pmc_mask(all_cfg_classes);
if (classes & KPC_CLASS_POWER_MASK)
mp_config.classes |= KPC_CLASS_CONFIGURABLE_MASK;
mp_config.cfg_state_mask = kpc_get_configurable_pmc_mask(classes);
return kpc_set_running_arch(&mp_config);
}
boolean_t
kpc_register_pm_handler(kpc_pm_handler_t handler)
{
return kpc_reserve_pm_counters(0x38, handler, TRUE);
}
boolean_t
kpc_reserve_pm_counters(uint64_t pmc_mask, kpc_pm_handler_t handler,
boolean_t custom_config)
{
uint64_t all_mask = (1ULL << kpc_configurable_count()) - 1;
uint64_t req_mask = 0ULL;
assert(handler != NULL);
assert(kpc_pm_handler == NULL);
req_mask = (pmc_mask & all_mask);
assert(kpc_popcount(req_mask) <= kpc_configurable_count());
kpc_pm_has_custom_config = custom_config;
kpc_pm_pmc_mask = req_mask;
kpc_pm_handler = handler;
printf("kpc: pm registered pmc_mask=%llx custom_config=%d\n",
req_mask, custom_config);
{
uint32_t cfg_count = kpc_get_counter_count(KPC_CLASS_CONFIGURABLE_MASK);
uint32_t pwr_count = kpc_popcount(kpc_pm_pmc_mask);
#pragma unused(cfg_count, pwr_count)
assert((cfg_count + pwr_count) == kpc_configurable_count());
}
return force_all_ctrs ? FALSE : TRUE;
}
void
kpc_release_pm_counters(void)
{
assert(kpc_pm_handler != NULL);
kpc_pm_has_custom_config = FALSE;
kpc_pm_pmc_mask = 0ULL;
kpc_pm_handler = NULL;
printf("kpc: pm released counters\n");
assert(kpc_get_counter_count(KPC_CLASS_CONFIGURABLE_MASK) == kpc_configurable_count());
}
uint8_t
kpc_popcount(uint64_t value)
{
return __builtin_popcountll(value);
}
uint64_t
kpc_get_configurable_pmc_mask(uint32_t classes)
{
uint32_t configurable_count = kpc_configurable_count();
uint64_t cfg_mask = 0ULL, pwr_mask = 0ULL, all_cfg_pmcs_mask = 0ULL;
if (((classes & (KPC_CLASS_CONFIGURABLE_MASK | KPC_CLASS_POWER_MASK)) == 0) ||
(configurable_count == 0))
{
goto exit;
}
assert(configurable_count < 64);
all_cfg_pmcs_mask = (1ULL << configurable_count) - 1;
if (classes & KPC_CLASS_CONFIGURABLE_MASK) {
if (force_all_ctrs == TRUE)
cfg_mask |= all_cfg_pmcs_mask;
else
cfg_mask |= (~kpc_pm_pmc_mask) & all_cfg_pmcs_mask;
}
if ((force_all_ctrs == FALSE) &&
(kpc_pm_handler != NULL) &&
(kpc_pm_has_custom_config == FALSE) &&
(classes & KPC_CLASS_POWER_MASK))
{
pwr_mask |= kpc_pm_pmc_mask & all_cfg_pmcs_mask;
}
exit:
assert( ((cfg_mask | pwr_mask) & (~all_cfg_pmcs_mask)) == 0 );
assert( kpc_popcount(cfg_mask | pwr_mask) <= kpc_configurable_count() );
assert( (cfg_mask & pwr_mask) == 0ULL );
return cfg_mask | pwr_mask;
}