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/*
* Copyright (c) 2015, 2016 embedded brains GmbH. All rights reserved.
*
* embedded brains GmbH
* Dornierstr. 4
* 82178 Puchheim
* Germany
* <rtems@embedded-brains.de>
*
* The license and distribution terms for this file may be
* found in the file LICENSE in this distribution or at
* http://www.rtems.org/license/LICENSE.
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include "tmacros.h"
#include <sys/lock.h>
#include <stdio.h>
#include <inttypes.h>
#include <rtems/test.h>
const char rtems_test_name[] = "TMFINE 1";
#define CPU_COUNT 32
#define MSG_COUNT 3
typedef struct {
uint32_t value;
} test_msg;
typedef struct {
rtems_test_parallel_context base;
rtems_id master;
rtems_id sema[CPU_COUNT];
rtems_id mq[CPU_COUNT];
uint32_t self_event_ops[CPU_COUNT][CPU_COUNT];
uint32_t all_to_one_event_ops[CPU_COUNT][CPU_COUNT];
uint32_t one_mutex_ops[CPU_COUNT][CPU_COUNT];
uint32_t many_mutex_ops[CPU_COUNT][CPU_COUNT];
uint32_t self_msg_ops[CPU_COUNT][CPU_COUNT];
uint32_t many_to_one_msg_ops[CPU_COUNT][CPU_COUNT];
uint32_t many_sys_lock_mutex_ops[CPU_COUNT][CPU_COUNT];
} test_context;
static test_context test_instance;
static rtems_interval test_duration(void)
{
return rtems_clock_get_ticks_per_second();
}
static rtems_interval test_init(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers
)
{
return test_duration();
}
static void test_fini(
const char *name,
uint32_t *counters,
size_t active_workers
)
{
size_t i;
printf(" <%s activeWorker=\"%zu\">\n", name, active_workers);
for (i = 0; i < active_workers; ++i) {
printf(
" <Counter worker=\"%zu\">%" PRIu32 "</Counter>\n",
i,
counters[i]
);
}
printf(" </%s>\n", name);
}
static void test_self_event_body(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers,
size_t worker_index
)
{
test_context *ctx = (test_context *) base;
rtems_id id = rtems_task_self();
uint32_t counter = 0;
while (!rtems_test_parallel_stop_job(&ctx->base)) {
rtems_status_code sc;
rtems_event_set out;
++counter;
sc = rtems_event_send(id, RTEMS_EVENT_0);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
sc = rtems_event_receive(
RTEMS_EVENT_0,
RTEMS_WAIT | RTEMS_EVENT_ANY,
RTEMS_NO_TIMEOUT,
&out
);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
}
ctx->self_event_ops[active_workers - 1][worker_index] = counter;
}
static void test_self_event_fini(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers
)
{
test_context *ctx = (test_context *) base;
test_fini(
"SelfEvent",
&ctx->self_event_ops[active_workers - 1][0],
active_workers
);
}
static void test_all_to_one_event_body(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers,
size_t worker_index
)
{
test_context *ctx = (test_context *) base;
rtems_id id = rtems_task_self();
bool is_master = rtems_test_parallel_is_master_worker(worker_index);
uint32_t counter = 0;
while (!rtems_test_parallel_stop_job(&ctx->base)) {
rtems_status_code sc;
++counter;
sc = rtems_event_send(id, RTEMS_EVENT_0);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
if (is_master) {
rtems_event_set out;
sc = rtems_event_receive(
RTEMS_ALL_EVENTS,
RTEMS_WAIT | RTEMS_EVENT_ANY,
RTEMS_NO_TIMEOUT,
&out
);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
}
}
ctx->all_to_one_event_ops[active_workers - 1][worker_index] = counter;
}
static void test_all_to_one_event_fini(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers
)
{
test_context *ctx = (test_context *) base;
test_fini(
"AllToOneEvent",
&ctx->all_to_one_event_ops[active_workers - 1][0],
active_workers
);
}
static void test_one_mutex_body(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers,
size_t worker_index
)
{
test_context *ctx = (test_context *) base;
rtems_id id = ctx->sema[0];
uint32_t counter = 0;
while (!rtems_test_parallel_stop_job(&ctx->base)) {
rtems_status_code sc;
++counter;
sc = rtems_semaphore_obtain(id, RTEMS_WAIT, RTEMS_NO_TIMEOUT);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
sc = rtems_semaphore_release(id);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
}
ctx->one_mutex_ops[active_workers - 1][worker_index] = counter;
}
static void test_one_mutex_fini(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers
)
{
test_context *ctx = (test_context *) base;
test_fini(
"OneMutex",
&ctx->one_mutex_ops[active_workers - 1][0],
active_workers
);
}
static void test_many_mutex_body(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers,
size_t worker_index
)
{
test_context *ctx = (test_context *) base;
rtems_id id = ctx->sema[worker_index];
uint32_t counter = 0;
while (!rtems_test_parallel_stop_job(&ctx->base)) {
rtems_status_code sc;
++counter;
sc = rtems_semaphore_obtain(id, RTEMS_WAIT, RTEMS_NO_TIMEOUT);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
sc = rtems_semaphore_release(id);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
}
ctx->many_mutex_ops[active_workers - 1][worker_index] = counter;
}
static void test_many_mutex_fini(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers
)
{
test_context *ctx = (test_context *) base;
test_fini(
"ManyMutex",
&ctx->many_mutex_ops[active_workers - 1][0],
active_workers
);
}
static void test_self_msg_body(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers,
size_t worker_index
)
{
test_context *ctx = (test_context *) base;
rtems_id id = ctx->mq[worker_index];
uint32_t counter = 0;
while (!rtems_test_parallel_stop_job(&ctx->base)) {
rtems_status_code sc;
test_msg msg = { .value = 0 };
size_t n;
++counter;
sc = rtems_message_queue_send(id, &msg, sizeof(msg));
rtems_test_assert(sc == RTEMS_SUCCESSFUL || sc == RTEMS_TOO_MANY);
n = sizeof(msg);
sc = rtems_message_queue_receive(
id,
&msg,
&n,
RTEMS_WAIT,
RTEMS_NO_TIMEOUT
);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
rtems_test_assert(n == sizeof(msg));
}
ctx->self_msg_ops[active_workers - 1][worker_index] = counter;
}
static void test_self_msg_fini(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers
)
{
test_context *ctx = (test_context *) base;
test_fini(
"SelfMsg",
&ctx->self_msg_ops[active_workers - 1][0],
active_workers
);
}
static void test_many_to_one_msg_body(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers,
size_t worker_index
)
{
test_context *ctx = (test_context *) base;
rtems_id id = ctx->mq[0];
bool is_master = rtems_test_parallel_is_master_worker(worker_index);
uint32_t counter = 0;
while (!rtems_test_parallel_stop_job(&ctx->base)) {
rtems_status_code sc;
test_msg msg = { .value = 0 };
size_t n;
++counter;
sc = rtems_message_queue_send(id, &msg, sizeof(msg));
rtems_test_assert(sc == RTEMS_SUCCESSFUL || sc == RTEMS_TOO_MANY);
if (is_master) {
n = sizeof(msg);
sc = rtems_message_queue_receive(
id,
&msg,
&n,
RTEMS_WAIT,
RTEMS_NO_TIMEOUT
);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
rtems_test_assert(n == sizeof(msg));
}
}
ctx->many_to_one_msg_ops[active_workers - 1][worker_index] = counter;
}
static void test_many_to_one_msg_fini(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers
)
{
test_context *ctx = (test_context *) base;
test_fini(
"ManyToOneMsg",
&ctx->many_to_one_msg_ops[active_workers - 1][0],
active_workers
);
}
static void test_many_sys_lock_mutex_body(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers,
size_t worker_index
)
{
test_context *ctx = (test_context *) base;
struct _Mutex_Control mtx;
uint32_t counter = 0;
_Mutex_Initialize(&mtx);
while (!rtems_test_parallel_stop_job(&ctx->base)) {
++counter;
_Mutex_Acquire(&mtx);
_Mutex_Release(&mtx);
}
ctx->many_sys_lock_mutex_ops[active_workers - 1][worker_index] = counter;
}
static void test_many_sys_lock_mutex_fini(
rtems_test_parallel_context *base,
void *arg,
size_t active_workers
)
{
test_context *ctx = (test_context *) base;
test_fini(
"ManySysLockMutex",
&ctx->many_sys_lock_mutex_ops[active_workers - 1][0],
active_workers
);
}
static const rtems_test_parallel_job test_jobs[] = {
{
.init = test_init,
.body = test_self_event_body,
.fini = test_self_event_fini,
.cascade = true
}, {
.init = test_init,
.body = test_all_to_one_event_body,
.fini = test_all_to_one_event_fini,
.cascade = true
}, {
.init = test_init,
.body = test_one_mutex_body,
.fini = test_one_mutex_fini,
.cascade = true
}, {
.init = test_init,
.body = test_many_mutex_body,
.fini = test_many_mutex_fini,
.cascade = true
}, {
.init = test_init,
.body = test_self_msg_body,
.fini = test_self_msg_fini,
.cascade = true
}, {
.init = test_init,
.body = test_many_to_one_msg_body,
.fini = test_many_to_one_msg_fini,
.cascade = true
}, {
.init = test_init,
.body = test_many_sys_lock_mutex_body,
.fini = test_many_sys_lock_mutex_fini,
.cascade = true
}
};
static void Init(rtems_task_argument arg)
{
test_context *ctx = &test_instance;
const char *test = "TestTimeFine01";
size_t i;
TEST_BEGIN();
ctx->master = rtems_task_self();
for (i = 0; i < CPU_COUNT; ++i) {
rtems_status_code sc;
sc = rtems_semaphore_create(
rtems_build_name('T', 'E', 'S', 'T'),
1,
RTEMS_BINARY_SEMAPHORE | RTEMS_INHERIT_PRIORITY | RTEMS_PRIORITY,
0,
&ctx->sema[i]
);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
sc = rtems_message_queue_create(
rtems_build_name('T', 'E', 'S', 'T'),
MSG_COUNT,
sizeof(test_msg),
RTEMS_DEFAULT_ATTRIBUTES,
&ctx->mq[i]
);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
}
printf("<%s>\n", test);
rtems_test_parallel(
&ctx->base,
NULL,
&test_jobs[0],
RTEMS_ARRAY_SIZE(test_jobs)
);
printf("</%s>\n", test);
TEST_END();
rtems_test_exit(0);
}
#define CONFIGURE_APPLICATION_NEEDS_CLOCK_DRIVER
#define CONFIGURE_APPLICATION_NEEDS_CONSOLE_DRIVER
#define CONFIGURE_MAXIMUM_TASKS CPU_COUNT
#define CONFIGURE_MAXIMUM_TIMERS 1
#define CONFIGURE_MAXIMUM_SEMAPHORES CPU_COUNT
#define CONFIGURE_MAXIMUM_MESSAGE_QUEUES CPU_COUNT
#define CONFIGURE_MESSAGE_BUFFER_MEMORY \
CONFIGURE_MESSAGE_BUFFERS_FOR_QUEUE(MSG_COUNT, sizeof(test_msg))
#define CONFIGURE_INITIAL_EXTENSIONS RTEMS_TEST_INITIAL_EXTENSION
#define CONFIGURE_RTEMS_INIT_TASKS_TABLE
#define CONFIGURE_SMP_APPLICATION
#define CONFIGURE_SMP_MAXIMUM_PROCESSORS CPU_COUNT
#define CONFIGURE_INIT
#include <rtems/confdefs.h>
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