/* * Copyright (c) 2014-2015, Siemens AG. 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 COPYRIGHT HOLDERS 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 COPYRIGHT HOLDER 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. */ #ifndef CONTAINERS_CPP_TEST_QUEUE_TEST_INL_H_ #define CONTAINERS_CPP_TEST_QUEUE_TEST_INL_H_ #include #include namespace embb { namespace containers { namespace test { template QueueTest::QueueTest() : n_threads(static_cast(partest::TestSuite::GetDefaultNumThreads())), n_queue_size( static_cast(partest::TestSuite::GetDefaultNumIterations()) * MIN_TOTAL_PRODUCE_CONSUME_COUNT), n_total_produce_consume_count(n_queue_size), n_producers(1), n_consumers(1), next_producer_id(0), next_consumer_id(0), n_producer_elements( static_cast(partest::TestSuite::GetDefaultNumIterations() * MIN_ENQ_ELEMENTS)) { CreateUnit("QueueTestSingleThreadEnqueueDequeue"). Pre(&QueueTest::QueueTestSingleThreadEnqueueDequeue_Pre, this). Add(&QueueTest::QueueTestSingleThreadEnqueueDequeue_ThreadMethod, this). Post(&QueueTest::QueueTestSingleThreadEnqueueDequeue_Post, this); CreateUnit("QueueTestTwoThreadsSingleProducerSingleConsumer"). Pre(&QueueTest::QueueTestSingleProducerSingleConsumer_Pre, this). Add(&QueueTest::QueueTestSingleProducerSingleConsumer_ThreadMethod, this, 2, static_cast(n_total_produce_consume_count)). Post(&QueueTest::QueueTestSingleProducerSingleConsumer_Post, this); #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable:4127) #endif if (MultipleProducers == true && MultipleConsumers == true) { // MP/MC n_producers = n_threads / 2; n_consumers = n_threads / 2; #ifdef _MSC_VER #pragma warning(pop) #endif CreateUnit("QueueTestOrderMultipleProducerMultipleConsumer"). Pre(&QueueTest::QueueTestOrderMPMC_Pre, this). Add(&QueueTest::QueueTestOrderMPMC_ConsumerThreadMethod, this, static_cast(n_consumers), static_cast(1)). Add(&QueueTest::QueueTestOrderMPMC_ProducerThreadMethod, this, static_cast(n_producers), static_cast(1)). Post(&QueueTest::QueueTestOrderMPMC_Post, this); } } template void QueueTest:: QueueTestOrderMPMC_Pre() { queue = new Queue_t(static_cast(n_producer_elements)); embb_internal_thread_index_reset(); next_producer_id = 0; next_consumer_id = 0; consumers.clear(); producers.clear(); for (size_t p = 0; p < static_cast(n_producers); ++p) { producers.push_back(Producer(queue, p, n_producer_elements)); } for (size_t c = 0; c < static_cast(n_consumers); ++c) { consumers.push_back(Consumer(queue, n_producers, n_producer_elements)); } } template void QueueTest:: QueueTestOrderMPMC_Post() { delete queue; // Tally for all elements enqueued by all producers, // initialized with all 0: ::std::vector total_tally; size_t n_elements_total = static_cast(n_producers * n_producer_elements); for (size_t i = 0; i < n_elements_total / 8; ++i) { total_tally.push_back(0); } // Collect all dequeued element flags from consumers: for (size_t c = 0; c < static_cast(n_consumers); ++c) { for (size_t e = 0; e < n_elements_total / 8; ++e) { total_tally[e] |= consumers[c].Tally()[e]; } } // Test if all elements have been dequeued by any // consumer. // To avoid static cast warning: for (size_t t = 0; t < static_cast(n_producers * n_producer_elements / 8); ++t) { PT_ASSERT_EQ_MSG(static_cast(total_tally[t]), 0xff, "missing dequeued elements"); } } template void QueueTest:: QueueTestOrderMPMC_ProducerThreadMethod() { size_t p_id = next_producer_id.FetchAndAdd(1); producers[p_id].Run(); } template void QueueTest:: QueueTestOrderMPMC_ConsumerThreadMethod() { size_t c_id = next_consumer_id.FetchAndAdd(1); consumers[c_id].Run(); } template void QueueTest::Producer:: Run() { // Enqueue pairs of (producer id, counter): for (int i = 0; i < n_producer_elements; ++i) { while (!q->TryEnqueue(element_t(producer_id, i))) { embb::base::Thread::CurrentYield(); } } // Enqueue -1 as terminator element of this producer: while (!q->TryEnqueue(element_t(producer_id, -1))) { embb::base::Thread::CurrentYield(); } } template QueueTest::Consumer:: Consumer(Queue_t * const queue, int numProducers, int numProducerElements) : q(queue), n_producers(numProducers), n_producer_elements(numProducerElements) { for (int p_id = 0; p_id < n_producers; ++p_id) { // Initialize last value dequeued from producers with // below-minimum value: sequence_number.push_back(-1); // Initialize element tally for producer with all 0, // 8 flags / char: for (int i = 0; i < n_producer_elements / 8; ++i) { consumer_tally.push_back(0); } } } template void QueueTest::Consumer:: Run() { element_t element; size_t producerId; // To avoid compiler warning bool forever = true; while (forever) { if (!q->TryDequeue(element)) { continue; } if (element.second < 0) { break; } producerId = element.first; // Assert on dequeued element: PT_ASSERT_LT_MSG(producerId, static_cast(n_producers), "Invalid producer id in dequeue"); PT_ASSERT_LT_MSG(sequence_number[producerId], element.second, "Invalid element sequence"); // Store last value received from the element's producer: sequence_number[producerId] = element.second; const size_t pos((producerId * n_producer_elements) + static_cast(element.second)); // Test dequeued element's position flag: tally[pos] == 1 PT_ASSERT_EQ_MSG(consumer_tally[pos / 8] & (0x80 >> (pos % 8)), 0, "Element dequeued twice"); // Set flag at dequeued element's position: // tally[pos] = 1 consumer_tally[pos / 8] |= (0x80 >> (pos % 8)); } } template void QueueTest:: QueueTestSingleProducerSingleConsumer_Pre() { embb_internal_thread_index_reset(); queue = new Queue_t(static_cast(n_queue_size)); thread_selector_producer = -1; produce_count = 0; consume_count = 0; consumed_elements.clear(); produced_elements.clear(); } template void QueueTest:: QueueTestSingleProducerSingleConsumer_Post() { embb_atomic_memory_barrier(); ::std::sort(consumed_elements.begin(), consumed_elements.end()); ::std::sort(produced_elements.begin(), produced_elements.end()); PT_ASSERT(consumed_elements.size() == produced_elements.size()); for (unsigned int i = 0; i != static_cast(consumed_elements.size()); i++) { PT_ASSERT(consumed_elements[i] == produced_elements[i]); } delete queue; } template void QueueTest:: QueueTestSingleProducerSingleConsumer_ThreadMethod() { unsigned int thread_index; int return_val = embb_internal_thread_index(&thread_index); PT_ASSERT(return_val == EMBB_SUCCESS); if (thread_selector_producer == -1) { int expected = -1; thread_selector_producer.CompareAndSwap(expected, static_cast(thread_index)); while (thread_selector_producer == -1) {} } if (static_cast(thread_selector_producer.Load()) == thread_index) { // we are the producer while (produce_count >= n_queue_size) { } element_t random_var(0, rand() % 10000); bool success = queue->TryEnqueue(random_var); PT_ASSERT(success == true); produce_count++; produced_elements.push_back(random_var); } else { // we are the consumer while (consume_count < n_total_produce_consume_count) { consume_count++; while (produce_count == 0) {} element_t consumed; bool success = queue->TryDequeue(consumed); PT_ASSERT(success == true); produce_count--; consumed_elements.push_back(consumed); } } } template void QueueTest:: QueueTestSingleThreadEnqueueDequeue_ThreadMethod() { // Enqueue the expected amount of elements for (int i = 0; i != n_queue_size; ++i) { bool success = queue->TryEnqueue(element_t(0, i * 133)); PT_ASSERT(success == true); } // Some queues may allow enqueueing more elements than their capacity // permits, so try to enqueue additional elements until the queue is full int oversized_count = n_queue_size; while ( queue->TryEnqueue(element_t(0, oversized_count * 133)) ) { ++oversized_count; } // Oversized amount should not be larger than the original capacity PT_ASSERT_LT(oversized_count, 2 * n_queue_size); // Dequeue the expected amount of elements for (int i = 0; i != n_queue_size; ++i) { element_t dequ(0, -1); bool success = queue->TryDequeue(dequ); PT_ASSERT(success == true); PT_ASSERT(dequ.second == i * 133); } // Dequeue any elements enqueued above the original capacity for (int i = n_queue_size; i != oversized_count; ++i) { element_t dequ(0, -1); bool success = queue->TryDequeue(dequ); PT_ASSERT(success == true); PT_ASSERT(dequ.second == i * 133); } // Ensure the queue is now empty { element_t dequ; bool success = queue->TryDequeue(dequ); PT_ASSERT(success == false); } } template void QueueTest:: QueueTestSingleThreadEnqueueDequeue_Pre() { queue = new Queue_t(static_cast(n_queue_size)); } template void QueueTest:: QueueTestSingleThreadEnqueueDequeue_Post() { delete queue; } } // namespace test } // namespace containers } // namespace embb #endif // CONTAINERS_CPP_TEST_QUEUE_TEST_INL_H_