/* * * Copyright 2015 gRPC authors. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * */ #include "src/core/lib/iomgr/port.h" #include "src/core/lib/iomgr/timer_heap.h" #include #include #include #include #include "src/core/lib/gpr/useful.h" #include "test/core/util/test_config.h" static gpr_atm random_deadline(void) { return rand(); } static grpc_timer* create_test_elements(size_t num_elements) { grpc_timer* elems = static_cast(gpr_malloc(num_elements * sizeof(grpc_timer))); size_t i; for (i = 0; i < num_elements; i++) { elems[i].deadline = random_deadline(); } return elems; } static int contains(grpc_timer_heap* pq, grpc_timer* el) { size_t i; for (i = 0; i < pq->timer_count; i++) { if (pq->timers[i] == el) return 1; } return 0; } static void check_valid(grpc_timer_heap* pq) { size_t i; for (i = 0; i < pq->timer_count; ++i) { size_t left_child = 1u + 2u * i; size_t right_child = left_child + 1u; if (left_child < pq->timer_count) { GPR_ASSERT(pq->timers[i]->deadline <= pq->timers[left_child]->deadline); } if (right_child < pq->timer_count) { GPR_ASSERT(pq->timers[i]->deadline <= pq->timers[right_child]->deadline); } } } /******************************************************************************* * test1 */ static void test1(void) { grpc_timer_heap pq; const size_t num_test_elements = 200; const size_t num_test_operations = 10000; size_t i; grpc_timer* test_elements = create_test_elements(num_test_elements); uint8_t* inpq = static_cast(gpr_malloc(num_test_elements)); gpr_log(GPR_INFO, "test1"); grpc_timer_heap_init(&pq); memset(inpq, 0, num_test_elements); GPR_ASSERT(grpc_timer_heap_is_empty(&pq)); check_valid(&pq); for (i = 0; i < num_test_elements; ++i) { GPR_ASSERT(!contains(&pq, &test_elements[i])); grpc_timer_heap_add(&pq, &test_elements[i]); check_valid(&pq); GPR_ASSERT(contains(&pq, &test_elements[i])); inpq[i] = 1; } for (i = 0; i < num_test_elements; ++i) { /* Test that check still succeeds even for element that wasn't just inserted. */ GPR_ASSERT(contains(&pq, &test_elements[i])); } GPR_ASSERT(pq.timer_count == num_test_elements); check_valid(&pq); for (i = 0; i < num_test_operations; ++i) { size_t elem_num = static_cast(rand()) % num_test_elements; grpc_timer* el = &test_elements[elem_num]; if (!inpq[elem_num]) { /* not in pq */ GPR_ASSERT(!contains(&pq, el)); el->deadline = random_deadline(); grpc_timer_heap_add(&pq, el); GPR_ASSERT(contains(&pq, el)); inpq[elem_num] = 1; check_valid(&pq); } else { GPR_ASSERT(contains(&pq, el)); grpc_timer_heap_remove(&pq, el); GPR_ASSERT(!contains(&pq, el)); inpq[elem_num] = 0; check_valid(&pq); } } grpc_timer_heap_destroy(&pq); gpr_free(test_elements); gpr_free(inpq); } /******************************************************************************* * test2 */ typedef struct { grpc_timer elem; bool inserted; } elem_struct; static elem_struct* search_elems(elem_struct* elems, size_t count, bool inserted) { size_t* search_order = static_cast(gpr_malloc(count * sizeof(*search_order))); for (size_t i = 0; i < count; i++) { search_order[i] = i; } for (size_t i = 0; i < count * 2; i++) { size_t a = static_cast(rand()) % count; size_t b = static_cast(rand()) % count; GPR_SWAP(size_t, search_order[a], search_order[b]); } elem_struct* out = nullptr; for (size_t i = 0; out == nullptr && i < count; i++) { if (elems[search_order[i]].inserted == inserted) { out = &elems[search_order[i]]; } } gpr_free(search_order); return out; } static void test2(void) { gpr_log(GPR_INFO, "test2"); grpc_timer_heap pq; static const size_t elems_size = 1000; elem_struct* elems = static_cast(gpr_malloc(elems_size * sizeof(elem_struct))); size_t num_inserted = 0; grpc_timer_heap_init(&pq); memset(elems, 0, elems_size); for (size_t round = 0; round < 10000; round++) { int r = rand() % 1000; if (r <= 550) { /* 55% of the time we try to add something */ elem_struct* el = search_elems(elems, GPR_ARRAY_SIZE(elems), false); if (el != nullptr) { el->elem.deadline = random_deadline(); grpc_timer_heap_add(&pq, &el->elem); el->inserted = true; num_inserted++; check_valid(&pq); } } else if (r <= 650) { /* 10% of the time we try to remove something */ elem_struct* el = search_elems(elems, GPR_ARRAY_SIZE(elems), true); if (el != nullptr) { grpc_timer_heap_remove(&pq, &el->elem); el->inserted = false; num_inserted--; check_valid(&pq); } } else { /* the remaining times we pop */ if (num_inserted > 0) { grpc_timer* top = grpc_timer_heap_top(&pq); grpc_timer_heap_pop(&pq); for (size_t i = 0; i < elems_size; i++) { if (top == &elems[i].elem) { GPR_ASSERT(elems[i].inserted); elems[i].inserted = false; } } num_inserted--; check_valid(&pq); } } if (num_inserted) { grpc_millis* min_deadline = nullptr; for (size_t i = 0; i < elems_size; i++) { if (elems[i].inserted) { if (min_deadline == nullptr) { min_deadline = &elems[i].elem.deadline; } else { if (elems[i].elem.deadline < *min_deadline) { min_deadline = &elems[i].elem.deadline; } } } } GPR_ASSERT(grpc_timer_heap_top(&pq)->deadline == *min_deadline); } } grpc_timer_heap_destroy(&pq); gpr_free(elems); } static void shrink_test(void) { gpr_log(GPR_INFO, "shrink_test"); grpc_timer_heap pq; size_t i; size_t expected_size; /* A large random number to allow for multiple shrinkages, at least 512. */ const size_t num_elements = static_cast(rand()) % 2000 + 512; grpc_timer_heap_init(&pq); /* Create a priority queue with many elements. Make sure the Size() is correct. */ for (i = 0; i < num_elements; ++i) { GPR_ASSERT(i == pq.timer_count); grpc_timer_heap_add(&pq, create_test_elements(1)); } GPR_ASSERT(num_elements == pq.timer_count); /* Remove elements until the Size is 1/4 the original size. */ while (pq.timer_count > num_elements / 4) { grpc_timer* const te = pq.timers[pq.timer_count - 1]; grpc_timer_heap_remove(&pq, te); gpr_free(te); } GPR_ASSERT(num_elements / 4 == pq.timer_count); /* Expect that Capacity is in the right range: Size * 2 <= Capacity <= Size * 4 */ GPR_ASSERT(pq.timer_count * 2 <= pq.timer_capacity); GPR_ASSERT(pq.timer_capacity <= pq.timer_count * 4); check_valid(&pq); /* Remove the rest of the elements. Check that the Capacity is not more than 4 times the Size and not less than 2 times, but never goes below 16. */ expected_size = pq.timer_count; while (pq.timer_count > 0) { const size_t which = static_cast(rand()) % pq.timer_count; grpc_timer* te = pq.timers[which]; grpc_timer_heap_remove(&pq, te); gpr_free(te); expected_size--; GPR_ASSERT(expected_size == pq.timer_count); GPR_ASSERT(pq.timer_count * 2 <= pq.timer_capacity); if (pq.timer_count >= 8) { GPR_ASSERT(pq.timer_capacity <= pq.timer_count * 4); } else { GPR_ASSERT(16 <= pq.timer_capacity); } check_valid(&pq); } GPR_ASSERT(0 == pq.timer_count); GPR_ASSERT(pq.timer_capacity >= 16 && pq.timer_capacity < 32); grpc_timer_heap_destroy(&pq); } int main(int argc, char** argv) { int i; grpc::testing::TestEnvironment env(argc, argv); for (i = 0; i < 5; i++) { test1(); test2(); shrink_test(); } return 0; }