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465 lines
13 KiB
C++
465 lines
13 KiB
C++
/**
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* Copyright 2013-2021 Software Radio Systems Limited
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*
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* This file is part of srsRAN.
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*
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* srsRAN is free software: you can redistribute it and/or modify
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* it under the terms of the GNU Affero General Public License as
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* published by the Free Software Foundation, either version 3 of
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* the License, or (at your option) any later version.
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*
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* srsRAN is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU Affero General Public License for more details.
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*
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* A copy of the GNU Affero General Public License can be found in
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* the LICENSE file in the top-level directory of this distribution
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* and at http://www.gnu.org/licenses/.
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*
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*/
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#include "srsran/common/test_common.h"
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#include "srsran/common/timers.h"
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#include <iostream>
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#include <random>
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#include <srsran/common/tti_sync_cv.h>
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#include <thread>
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using namespace srsran;
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int timers_test1()
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{
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timer_handler timers;
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uint32_t dur = 5;
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{
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// TEST: default ctor places unique_timer in correct state
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timer_handler::unique_timer t = timers.get_unique_timer();
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TESTASSERT(not t.is_running() and not t.is_expired());
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TESTASSERT(t.id() == 0);
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timer_handler::unique_timer t2 = timers.get_unique_timer();
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TESTASSERT(not t2.is_running() and not t2.is_expired());
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TESTASSERT(t2.id() == 1);
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TESTASSERT(timers.nof_timers() == 2);
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// TEST: Run multiple times with the same duration
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bool callback_called = false;
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t.set(dur, [&callback_called](int tid) { callback_called = true; });
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for (uint32_t runs = 0; runs < 3; ++runs) {
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callback_called = false;
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TESTASSERT(not t.is_running());
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t.run();
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TESTASSERT(t.is_running() and not t.is_expired());
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for (uint32_t i = 0; i < dur - 1; ++i) {
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timers.step_all();
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TESTASSERT(t.is_running() and not t.is_expired());
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}
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timers.step_all();
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TESTASSERT(not t.is_running() and t.is_expired());
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TESTASSERT(callback_called);
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}
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// TEST: interrupt a timer. check if callback was called
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callback_called = false;
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t.run();
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timers.step_all();
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TESTASSERT(t.is_running());
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t.stop();
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TESTASSERT(not t.is_running());
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for (uint32_t i = 0; i < dur; ++i) {
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timers.step_all();
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TESTASSERT(not t.is_running());
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}
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TESTASSERT(not callback_called);
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// TEST: call timer::run() when it is already running. Check if duration gets extended.
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callback_called = false;
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t.run();
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timers.step_all();
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TESTASSERT(t.is_running());
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t.run(); // re-run
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for (uint32_t i = 0; i < dur - 1; ++i) {
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timers.step_all();
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TESTASSERT(t.is_running());
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}
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timers.step_all();
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TESTASSERT(not t.is_running());
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TESTASSERT(callback_called);
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// TEST: ordering of timers is respected
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timer_handler::unique_timer t3 = timers.get_unique_timer();
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TESTASSERT(t3.id() == 2);
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int first_id = -1, last_id = -1;
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auto callback = [&first_id, &last_id](int id) {
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if (first_id < 0) {
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printf("First timer id=%d\n", id);
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first_id = id;
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}
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last_id = id;
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};
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t.set(4, callback);
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t2.set(2, callback);
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t3.set(6, callback);
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t.run();
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t2.run();
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t3.run();
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for (uint32_t i = 0; i < 5; ++i) {
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timers.step_all();
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TESTASSERT(i >= 3 or t.is_running());
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TESTASSERT(i >= 1 or t2.is_running());
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TESTASSERT(t3.is_running());
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}
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timers.step_all();
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TESTASSERT(t.is_expired() and t2.is_expired() and t3.is_expired());
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TESTASSERT(first_id == 1);
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TESTASSERT(last_id == 2);
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}
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// TEST: timer dtor is called and removes "timer" from "timers"
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TESTASSERT(timers.nof_timers() == 0);
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return SRSRAN_SUCCESS;
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}
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/**
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* Description:
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* - calling stop() early, forbids the timer from getting expired
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* - calling stop() after timer has expired should be a noop
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*/
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int timers_test2()
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{
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timer_handler timers;
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uint32_t duration = 2;
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auto utimer = timers.get_unique_timer();
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auto utimer2 = timers.get_unique_timer();
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utimer.set(duration);
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utimer2.set(duration);
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// TEST 1: call utimer.stop() early and check if timer expires
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utimer.run();
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utimer2.run();
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TESTASSERT(utimer.is_running() and not utimer.is_expired());
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utimer.stop();
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TESTASSERT(not utimer.is_running() and not utimer.is_expired());
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for (uint32_t i = 0; i < 5; ++i) {
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timers.step_all();
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}
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TESTASSERT(not utimer.is_expired());
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TESTASSERT(utimer2.is_expired());
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// TEST 2: call utimer.stop() after it expires and assert it is still expired
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utimer2.stop();
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TESTASSERT(utimer2.is_expired());
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return SRSRAN_SUCCESS;
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}
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/**
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* Description:
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* - setting a new duration while the timer is already running should not stop timer, and should extend timeout
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*/
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int timers_test3()
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{
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timer_handler timers;
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uint32_t duration = 5;
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auto utimer = timers.get_unique_timer();
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utimer.set(duration);
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utimer.run();
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for (uint32_t i = 0; i < 2 * duration + 1; ++i) {
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timers.step_all();
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if ((i % 2) == 0) {
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// extends lifetime
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utimer.set(duration);
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}
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TESTASSERT(utimer.is_running());
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}
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for (uint32_t i = 0; i < duration - 1; ++i) {
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timers.step_all();
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TESTASSERT(utimer.is_running());
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}
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timers.step_all();
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TESTASSERT(not utimer.is_running() and utimer.is_expired());
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return SRSRAN_SUCCESS;
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}
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struct timers_test4_ctxt {
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std::vector<timer_handler::unique_timer> timers;
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srsran::tti_sync_cv tti_sync1;
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srsran::tti_sync_cv tti_sync2;
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const uint32_t duration = 1000;
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};
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static void timers2_test4_thread(timers_test4_ctxt* ctx)
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{
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std::mt19937 mt19937(4);
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std::uniform_real_distribution<float> real_dist(0.0f, 1.0f);
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for (uint32_t d = 0; d < ctx->duration; d++) {
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// make random events
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for (uint32_t i = 1; i < ctx->timers.size(); i++) {
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if (0.1f > real_dist(mt19937)) {
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ctx->timers[i].run();
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}
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if (0.1f > real_dist(mt19937)) {
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ctx->timers[i].stop();
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}
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if (0.1f > real_dist(mt19937)) {
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ctx->timers[i].set(static_cast<uint32_t>(ctx->duration * real_dist(mt19937)));
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ctx->timers[i].run();
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}
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}
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// Send finished to main thread
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ctx->tti_sync1.increase();
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// Wait to main thread to check results
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ctx->tti_sync2.wait();
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}
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}
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int timers_test4()
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{
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timers_test4_ctxt* ctx = new timers_test4_ctxt;
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timer_handler timers;
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uint32_t nof_timers = 32;
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std::mt19937 mt19937(4);
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std::uniform_real_distribution<float> real_dist(0.0f, 1.0f);
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// Generate all timers and start them
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for (uint32_t i = 0; i < nof_timers; i++) {
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ctx->timers.push_back(timers.get_unique_timer());
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ctx->timers[i].set(ctx->duration);
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ctx->timers[i].run();
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}
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// Create side thread
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std::thread thread(timers2_test4_thread, ctx);
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for (uint32_t d = 0; d < ctx->duration; d++) {
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// make random events
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for (uint32_t i = 1; i < nof_timers; i++) {
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if (0.1f > real_dist(mt19937)) {
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ctx->timers[i].run();
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}
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if (0.1f > real_dist(mt19937)) {
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ctx->timers[i].stop();
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}
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if (0.1f > real_dist(mt19937)) {
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ctx->timers[i].set(static_cast<uint32_t>(ctx->duration * real_dist(mt19937)));
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ctx->timers[i].run();
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}
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}
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// first times, does not have event, it shall keep running
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TESTASSERT(ctx->timers[0].is_running());
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// Increment time
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timers.step_all();
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// wait second thread to finish events
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ctx->tti_sync1.wait();
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// assert no timer got wrong values
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for (uint32_t i = 0; i < nof_timers; i++) {
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if (ctx->timers[i].is_running()) {
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TESTASSERT(ctx->timers[i].time_elapsed() <= ctx->timers[i].duration());
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}
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}
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// Start new TTI
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ctx->tti_sync2.increase();
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}
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// Finish asynchronous thread
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thread.join();
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// First timer should have expired
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TESTASSERT(ctx->timers[0].is_expired());
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TESTASSERT(not ctx->timers[0].is_running());
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// Run for the maximum period
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for (uint32_t d = 0; d < ctx->duration; d++) {
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timers.step_all();
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}
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// No timer should be running
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for (uint32_t i = 0; i < nof_timers; i++) {
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TESTASSERT(not ctx->timers[i].is_running());
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}
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delete ctx;
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return SRSRAN_SUCCESS;
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}
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/**
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* Description: Delaying a callback using the timer_handler
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*/
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int timers_test5()
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{
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timer_handler timers;
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TESTASSERT(timers.nof_timers() == 0);
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TESTASSERT(timers.nof_running_timers() == 0);
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std::vector<int> vals;
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// TTI 0: Add a unique_timer of duration=5
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timer_handler::unique_timer t = timers.get_unique_timer();
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TESTASSERT(timers.nof_timers() == 1);
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t.set(5, [&vals](uint32_t tid) { vals.push_back(1); });
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t.run();
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TESTASSERT(timers.nof_running_timers() == 1);
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timers.step_all();
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// TTI 1: Add two delayed callbacks, with duration=2 and 6
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{
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// ensure captures by value are ok
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std::string string = "test string";
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timers.defer_callback(2, [&vals, string]() {
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vals.push_back(2);
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srsran_assert(string == "test string", "string was not captured correctly");
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});
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}
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timers.defer_callback(6, [&vals]() { vals.push_back(3); });
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TESTASSERT(timers.nof_timers() == 3);
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TESTASSERT(timers.nof_running_timers() == 3);
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timers.step_all();
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timers.step_all();
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// TTI 3: First callback should have been triggered by now
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TESTASSERT(timers.nof_running_timers() == 2);
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TESTASSERT(timers.nof_timers() == 2);
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TESTASSERT(vals.size() == 1);
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TESTASSERT(vals[0] == 2);
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timers.step_all();
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timers.step_all();
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// TTI 5: Unique timer should have been triggered by now
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TESTASSERT(timers.nof_running_timers() == 1);
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TESTASSERT(timers.nof_timers() == 2);
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TESTASSERT(vals.size() == 2);
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TESTASSERT(vals[1] == 1);
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timers.step_all();
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timers.step_all();
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// TTI 7: Second callback should have been triggered by now
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TESTASSERT(timers.nof_running_timers() == 0);
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TESTASSERT(timers.nof_timers() == 1);
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TESTASSERT(vals.size() == 3);
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TESTASSERT(vals[2] == 3);
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return SRSRAN_SUCCESS;
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}
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/**
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* Description: Check if erasure of a running timer is safe
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*/
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int timers_test6()
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{
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timer_handler timers;
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std::vector<int> vals;
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// Event: Add a timer that gets erased 1 tti after.
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{
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timer_handler::unique_timer t = timers.get_unique_timer();
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t.set(2, [&vals](uint32_t tid) { vals.push_back(1); });
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t.run();
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TESTASSERT(timers.nof_running_timers() == 1);
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timers.step_all();
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}
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TESTASSERT(timers.nof_running_timers() == 0);
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TESTASSERT(timers.nof_timers() == 0);
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// TEST: The timer callback should not have been called
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timers.step_all();
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TESTASSERT(vals.empty());
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// Event: Add a timer that gets erased right after, and add another timer with same timeout
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{
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timer_handler::unique_timer t = timers.get_unique_timer();
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t.set(2, [&vals](uint32_t tid) { vals.push_back(2); });
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t.run();
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TESTASSERT(timers.nof_running_timers() == 1);
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timers.step_all();
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TESTASSERT(t.time_elapsed() == 1);
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}
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timer_handler::unique_timer t = timers.get_unique_timer();
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t.set(1, [&vals](uint32_t tid) { vals.push_back(3); });
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t.run();
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TESTASSERT(timers.nof_running_timers() == 1);
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// TEST: The second timer's callback should be the one being called, and should be called only once
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timers.step_all();
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TESTASSERT(vals.size() == 1 and vals[0] == 3);
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return SRSRAN_SUCCESS;
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}
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/**
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* Tests specific to timer_handler wheel-based implementation:
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* - check if timer update is safe when its new updated wheel position matches the previous wheel position
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* - multime timers can exist in the same wheel position
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*/
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int timers_test7()
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{
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timer_handler timers;
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size_t wheel_size = timer_handler::get_wheel_size();
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unique_timer t = timers.get_unique_timer();
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t.set(2);
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t.run();
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timers.step_all();
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TESTASSERT(not t.is_expired() and t.is_running());
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// should fall in same wheel position as previous timer run
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t.set(1 + wheel_size);
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for (size_t i = 0; i < wheel_size; ++i) {
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timers.step_all();
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TESTASSERT(not t.is_expired() and t.is_running());
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}
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timers.step_all();
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TESTASSERT(t.is_expired() and not t.is_running());
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// the three timers will all fall in the same wheel position. However, only t and t3 should trigger
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unique_timer t2 = timers.get_unique_timer();
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unique_timer t3 = timers.get_unique_timer();
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t.set(5);
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t2.set(5 + wheel_size);
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t3.set(5);
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t.run();
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t2.run();
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t3.run();
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TESTASSERT(timers.nof_running_timers() == 3 and timers.nof_timers() == 3);
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for (size_t i = 0; i < 5; ++i) {
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TESTASSERT(not t.is_expired() and t.is_running());
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TESTASSERT(not t2.is_expired() and t2.is_running());
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TESTASSERT(not t3.is_expired() and t3.is_running());
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timers.step_all();
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}
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TESTASSERT(t.is_expired() and not t.is_running());
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TESTASSERT(not t2.is_expired() and t2.is_running());
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TESTASSERT(t3.is_expired() and not t3.is_running());
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TESTASSERT(timers.nof_running_timers() == 1 and timers.nof_timers() == 3);
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return SRSRAN_SUCCESS;
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}
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int main()
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{
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TESTASSERT(timers_test1() == SRSRAN_SUCCESS);
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TESTASSERT(timers_test2() == SRSRAN_SUCCESS);
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TESTASSERT(timers_test3() == SRSRAN_SUCCESS);
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TESTASSERT(timers_test4() == SRSRAN_SUCCESS);
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TESTASSERT(timers_test5() == SRSRAN_SUCCESS);
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TESTASSERT(timers_test6() == SRSRAN_SUCCESS);
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TESTASSERT(timers_test7() == SRSRAN_SUCCESS);
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printf("Success\n");
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return 0;
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}
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