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							/*
 * Copyright (c) 2014-2018 Remy Noel.
 * Copyright (c) 2014-2018 Richard Braun.
 *
 * This program is free software: you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation, either version 3 of the License, or
 * (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 *
 *
 * This test checks the behavior of performance monitoring on a CPU.
 * It creates a group with two events, cycle and instruction, and attaches
 * that group to CPU1, where a thread is bound and runs a tight loop to
 * make sure the target CPU is never idle. After some time, the measurement
 * stops and values are reported.
 */

#include <errno.h>
#include <stdbool.h>
#include <stddef.h>
#include <stdint.h>
#include <string.h>

#include <kern/atomic.h>
#include <kern/clock.h>
#include <kern/cpumap.h>
#include <kern/error.h>
#include <kern/list.h>
#include <kern/log.h>
#include <kern/panic.h>
#include <kern/perfmon.h>
#include <kern/thread.h>
#include <machine/cpu.h>
#include <test/test.h>

#define TEST_WAIT_DELAY_MS   1000

/*
 * Using another CPU than the BSP as the monitored CPU checks that PMUs are
 * correctly initialized on APs.
 */
#define TEST_CONTROL_CPU     0
#define TEST_MONITORED_CPU   (TEST_CONTROL_CPU + 1)
#define TEST_MIN_CPUS        (TEST_MONITORED_CPU + 1)

#define TEST_EVENT_NAME_MAX_SIZE   32

struct test_event
{
  struct list node;
  struct perfmon_event pm_event;
  char name[TEST_EVENT_NAME_MAX_SIZE];
};

struct test_group
{
  struct list events;
};

static uint32_t test_run_stop;

static void
test_wait (void)
{
  thread_delay (clock_ticks_from_ms (TEST_WAIT_DELAY_MS), false);
}

static void
test_event_init (struct test_event *event, uint32_t id, const char *name)
{
  int error = perfmon_event_init (&event->pm_event, id, PERFMON_EF_KERN);
  error_check (error, "perfmon_event_init");
  strlcpy (event->name, name, sizeof (event->name));
}

static void
test_event_report (struct test_event *event)
{
  uint64_t count = perfmon_event_read (&event->pm_event);
  int error = count ? 0 : EINVAL;
  error_check (error, __func__);
  log_info ("test: %s: %llu", event->name, count);
}

static void
test_event_attach_cpu (struct test_event *event, uint32_t cpu)
{
  int error = perfmon_event_attach_cpu (&event->pm_event, cpu);
  error_check (error, "perfmon_event_attach_cpu");
}

static void
test_event_detach (struct test_event *event)
{
  int error = perfmon_event_detach (&event->pm_event);
  error_check (error, "perfmon_event_detach");
}

static void
test_group_init (struct test_group *group)
{
  list_init (&group->events);
}

static void
test_group_add (struct test_group *group, struct test_event *event)
{
  list_insert_tail (&group->events, &event->node);
}

static void
test_group_attach_cpu (struct test_group *group, uint32_t cpu)
{
  struct test_event *event;
  list_for_each_entry (&group->events, event, node)
    test_event_attach_cpu (event, cpu);
}

static void
test_group_detach (struct test_group *group)
{
  struct test_event *event;
  list_for_each_entry (&group->events, event, node)
    test_event_detach (event);
}

static void
test_group_report (struct test_group *group)
{
  struct test_event *event;
  list_for_each_entry (&group->events, event, node)
    test_event_report (event);
}

static void
test_run (void *arg __unused)
{
  while (!atomic_load_rlx (&test_run_stop))
    cpu_pause ();
}

static void
test_control (void *arg)
{
  struct thread *thread = arg;
  struct test_event cycle, instruction;
  struct test_group group;

  test_event_init (&cycle, PERFMON_EV_CYCLE, "cycle");
  test_event_init (&instruction, PERFMON_EV_INSTRUCTION, "instruction");
  test_group_init (&group);
  test_group_add (&group, &cycle);
  test_group_add (&group, &instruction);
  test_group_attach_cpu (&group, TEST_MONITORED_CPU);
  test_wait ();
  test_group_report (&group);
  test_wait ();
  test_group_detach (&group);
  test_group_report (&group);

  atomic_store_rlx (&test_run_stop, 1);
  thread_join (thread);
  log_info ("test (perfmon_cpu): OK");
}

TEST_INLINE (perfmon_cpu)
{
  if (cpu_count () < TEST_MIN_CPUS)
    {
      log_err ("test: %u processors required", TEST_MIN_CPUS);
      return (TEST_SKIPPED);
    }

  struct cpumap *cpumap;
  int error = cpumap_create (&cpumap);
  error_check (error, "cpumap_create");

  struct thread_attr attr;
  thread_attr_init (&attr, THREAD_KERNEL_PREFIX "test_run");
  cpumap_zero (cpumap);
  cpumap_set (cpumap, TEST_MONITORED_CPU);
  thread_attr_set_cpumap (&attr, cpumap);

  struct thread *thread;
  error = thread_create (&thread, &attr, test_run, NULL);
  error_check (error, "thread_create");

  thread_attr_init (&attr, THREAD_KERNEL_PREFIX "test_control");
  thread_attr_set_detached (&attr);
  cpumap_zero (cpumap);
  cpumap_set (cpumap, TEST_CONTROL_CPU);
  thread_attr_set_cpumap (&attr, cpumap);
  error = thread_create (NULL, &attr, test_control, thread);
  error_check (error, "thread_create");

  cpumap_destroy (cpumap);
  return (TEST_RUNNING);
}