Micro template library A library for building device drivers
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deque.cpp 14 KiB

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  1. /*!
  2. * \file deque.cpp
  3. * \brief
  4. * Unit tests for deque
  5. *
  6. * \copyright Copyright (C) 2020 Christos Choutouridis <christos@choutouridis.net>
  7. *
  8. * <dl class=\"section copyright\"><dt>License</dt><dd>
  9. * The MIT License (MIT)
  10. *
  11. * Permission is hereby granted, free of charge, to any person obtaining a copy
  12. * of this software and associated documentation files (the "Software"), to deal
  13. * in the Software without restriction, including without limitation the rights
  14. * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
  15. * copies of the Software, and to permit persons to whom the Software is
  16. * furnished to do so, subject to the following conditions:
  17. *
  18. * The above copyright notice and this permission notice shall be included in all
  19. * copies or substantial portions of the Software.
  20. *
  21. * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
  22. * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
  23. * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
  24. * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
  25. * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
  26. * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
  27. * SOFTWARE.
  28. * </dd></dl>
  29. *
  30. */
  31. #include <utl/container/deque.h>
  32. //#include <utl/container/span.h>
  33. #include <gtest/gtest.h>
  34. #include <array>
  35. #include <type_traits>
  36. #include <cstring>
  37. #ifndef WIN_TRHEADS
  38. #include <mutex>
  39. #include <thread>
  40. #else
  41. #include <mingw.thread.h>
  42. #include <mingw.mutex.h>
  43. #endif
  44. namespace Tdeque {
  45. using namespace utl;
  46. // template <typename>
  47. // struct is_span : std::false_type {};
  48. //
  49. // template <typename T, std::size_t S>
  50. // struct is_span<tbx::span<T, S>> : std::true_type {};
  51. template <typename>
  52. struct is_std_array : std::false_type {};
  53. template <typename T, std::size_t N>
  54. struct is_std_array<std::array<T, N>> : std::true_type {};
  55. template <typename, typename = void>
  56. struct has_size_and_data : std::false_type {};
  57. template <typename T>
  58. struct has_size_and_data<T, std::void_t<decltype(std::declval<T>().size()),
  59. decltype(std::declval<T>().data())>>
  60. : std::true_type {};
  61. // Concept
  62. TEST(Tdeque, concept) {
  63. using deque_t = deque<int, 8>;
  64. EXPECT_EQ ( std::is_default_constructible<deque_t>::value, true);
  65. EXPECT_EQ ( std::is_nothrow_default_constructible<deque_t>::value, true);
  66. EXPECT_EQ (!std::is_copy_constructible<deque_t>::value, true);
  67. EXPECT_EQ (!std::is_copy_assignable<deque_t>::value, true);
  68. // EXPECT_EQ (true, !is_span<deque_t>::value);
  69. EXPECT_EQ (true, !is_std_array<deque_t>::value);
  70. EXPECT_EQ (true, !std::is_array<deque_t>::value);
  71. EXPECT_EQ (true, has_size_and_data<deque_t>::value);
  72. }
  73. // Test construction
  74. TEST(Tdeque, contruct) {
  75. deque<int, 8> q1;
  76. deque<int, 8> q2{1, 2, 3, 4, 5, 6, 7, 8};
  77. deque<int, 8> q3{1, 2, 3, 4, 5};
  78. EXPECT_EQ (8UL, q1.capacity());
  79. EXPECT_EQ (0UL, q1.size());
  80. EXPECT_EQ (8UL, q2.capacity());
  81. EXPECT_EQ (8UL, q2.size());
  82. EXPECT_EQ (8UL, q3.capacity());
  83. EXPECT_EQ (5UL, q3.size());
  84. }
  85. // simple push-pop functionality
  86. TEST(Tdeque, push_pop) {
  87. deque<int, 8> q1;
  88. deque<int, 8> q2{1, 2, 3, 4, 5, 6, 7, 8};
  89. q1.push_front(1);
  90. q1.push_front(2);
  91. EXPECT_EQ (1, q1.pop_back());
  92. EXPECT_EQ (2, q1.pop_back());
  93. q1.push_back(1);
  94. q1.push_back(2);
  95. EXPECT_EQ (1, q1.pop_front());
  96. EXPECT_EQ (2, q1.pop_front());
  97. q1.push_front(2);
  98. q1.push_back(3);
  99. q1.push_front(1);
  100. q1.push_back(4);
  101. for (int i=1 ; i<= 4 ; ++i)
  102. EXPECT_EQ ((int)i, q1.pop_front());
  103. }
  104. // front-back
  105. TEST(Tdeque, front_back) {
  106. deque<int, 8> q1;
  107. deque<int, 8> q2{1, 2, 3, 4, 5, 6, 7, 8};
  108. q1.push_front(2);
  109. q1.push_front(1);
  110. q1.push_back(3);
  111. q1.push_back(4);
  112. EXPECT_EQ (1, q1.front());
  113. EXPECT_EQ (4, q1.back());
  114. EXPECT_EQ (1, q2.front());
  115. EXPECT_EQ (8, q2.back());
  116. }
  117. // capacity
  118. TEST(Tdeque, capacity) {
  119. deque<int, 8> q1;
  120. deque<int, 8> q2{1, 2, 3, 4, 5, 6, 7, 8};
  121. q1.push_back(1);
  122. q1.clear();
  123. EXPECT_EQ (true, q1.empty());
  124. EXPECT_EQ (true, q2.full());
  125. EXPECT_EQ (8UL, q1.capacity());
  126. EXPECT_EQ (8UL, q2.capacity());
  127. EXPECT_EQ (0UL, q1.size());
  128. EXPECT_EQ (8UL, q2.size());
  129. q1.push_back(2);
  130. EXPECT_EQ (1UL, q1.size());
  131. q1.push_front(1);
  132. EXPECT_EQ (2UL, q1.size());
  133. q1.pop_back();
  134. EXPECT_EQ (1UL, q1.size());
  135. q1.pop_front();
  136. EXPECT_EQ (0UL, q1.size());
  137. }
  138. // push-pop limits
  139. TEST (Tdeque, push_pop_limits) {
  140. deque<int, 8> q1;
  141. deque<int, 8> q2{1, 2, 3, 4, 5, 6, 7, 8};
  142. EXPECT_EQ (int{}, q1.pop_back());
  143. EXPECT_EQ (0UL, q1.size());
  144. EXPECT_EQ (true, q1.empty());
  145. EXPECT_EQ (false, q1.full());
  146. EXPECT_EQ (int{}, q1.pop_front());
  147. EXPECT_EQ (0UL, q1.size());
  148. EXPECT_EQ (true, q1.empty());
  149. EXPECT_EQ (false, q1.full());
  150. q2.push_front(0);
  151. EXPECT_EQ (1, q2.front());
  152. EXPECT_EQ (8, q2.back());
  153. EXPECT_EQ (8UL, q2.size());
  154. EXPECT_EQ (false, q2.empty());
  155. EXPECT_EQ (true, q2.full());
  156. q2.push_back(9);
  157. EXPECT_EQ (1, q2.front());
  158. EXPECT_EQ (8, q2.back());
  159. EXPECT_EQ (8UL, q2.size());
  160. EXPECT_EQ (false, q2.empty());
  161. EXPECT_EQ (true, q2.full());
  162. }
  163. // iterators
  164. TEST (Tdeque, iterators) {
  165. deque<int, 8> q1{1, 2, 3, 4, 5, 6, 7, 8};
  166. int check_it=1;
  167. EXPECT_EQ (q1.begin().base(), q1.end().base());
  168. EXPECT_NE (q1.begin().iter(), q1.end().iter());
  169. EXPECT_EQ (1, *q1.begin());
  170. EXPECT_EQ (true, (q1.begin() == ++q1.end())); // loop edge iterators
  171. for (auto it = q1.begin() ; it != q1.end() ; ++it)
  172. EXPECT_EQ(*it, check_it++);
  173. EXPECT_EQ(9, check_it); // run through all
  174. EXPECT_EQ (1, q1.front()); // queue stays intact
  175. EXPECT_EQ (8, q1.back());
  176. EXPECT_EQ (8UL, q1.size());
  177. EXPECT_EQ (false, q1.empty());
  178. EXPECT_EQ (true, q1.full());
  179. q1.pop_front();
  180. q1.pop_back();
  181. check_it=2;
  182. for (auto& it : q1)
  183. EXPECT_EQ(it, check_it++);
  184. EXPECT_EQ(8, check_it); // run through all
  185. EXPECT_EQ (2, q1.front()); // queue stays intact
  186. EXPECT_EQ (7, q1.back());
  187. EXPECT_EQ (6UL, q1.size());
  188. EXPECT_EQ (false, q1.empty());
  189. EXPECT_EQ (false, q1.full());
  190. deque<int, 8> q2;
  191. q2.push_front(2);
  192. q2.push_front(1);
  193. q2.push_back(3);
  194. q2.push_back(4);
  195. q2.push_back(5);
  196. check_it =1;
  197. for (auto& it : q2)
  198. EXPECT_EQ(it, check_it++);
  199. EXPECT_EQ(6, check_it); // run through all
  200. }
  201. TEST (Tdeque, range) {
  202. deque<int, 8> q1{1, 2, 3, 4, 5, 6, 7, 8};
  203. int check_it=1;
  204. for (auto& it : q1.contents())
  205. EXPECT_EQ(it, check_it++);
  206. EXPECT_EQ(9, check_it); // run through all
  207. }
  208. // Concept
  209. TEST(Tdeque, concept_atomic) {
  210. using deque_t = deque<int, 8, true>;
  211. // EXPECT_EQ (true, !is_span<deque_t>::value);
  212. EXPECT_EQ (true, !is_std_array<deque_t>::value);
  213. EXPECT_EQ (true, !std::is_array<deque_t>::value);
  214. EXPECT_EQ (true, has_size_and_data<deque_t>::value);
  215. }
  216. // Test construction
  217. TEST(Tdeque, contruct_atomic) {
  218. deque<int, 8, true> q1;
  219. deque<int, 8, true> q2{1, 2, 3, 4, 5, 6, 7, 8};
  220. deque<int, 8, true> q3{1, 2, 3, 4, 5};
  221. EXPECT_EQ (8UL, q1.capacity());
  222. EXPECT_EQ (0UL, q1.size());
  223. EXPECT_EQ (8UL, q2.capacity());
  224. EXPECT_EQ (8UL, q2.size());
  225. EXPECT_EQ (8UL, q3.capacity());
  226. EXPECT_EQ (5UL, q3.size());
  227. }
  228. // simple push-pop functionality
  229. TEST(Tdeque, push_pop_atomic) {
  230. deque<int, 8, true> q1;
  231. deque<int, 8, true> q2{1, 2, 3, 4, 5, 6, 7, 8};
  232. q1.push_front(1);
  233. q1.push_front(2);
  234. EXPECT_EQ (1, q1.pop_back());
  235. EXPECT_EQ (2, q1.pop_back());
  236. q1.push_back(1);
  237. q1.push_back(2);
  238. EXPECT_EQ (1, q1.pop_front());
  239. EXPECT_EQ (2, q1.pop_front());
  240. q1.push_front(2);
  241. q1.push_back(3);
  242. q1.push_front(1);
  243. q1.push_back(4);
  244. for (int i=1 ; i<= 4 ; ++i)
  245. EXPECT_EQ ((int)i, q1.pop_front());
  246. }
  247. // front-back
  248. TEST(Tdeque, front_back_atomic) {
  249. deque<int, 8, true> q1;
  250. deque<int, 8, true> q2{1, 2, 3, 4, 5, 6, 7, 8};
  251. q1.push_front(2);
  252. q1.push_front(1);
  253. q1.push_back(3);
  254. q1.push_back(4);
  255. EXPECT_EQ (1, q1.front());
  256. EXPECT_EQ (4, q1.back());
  257. EXPECT_EQ (1, q2.front());
  258. EXPECT_EQ (8, q2.back());
  259. }
  260. // capacity
  261. TEST(Tdeque, capacity_atomic) {
  262. deque<int, 8, true> q1;
  263. deque<int, 8, true> q2{1, 2, 3, 4, 5, 6, 7, 8};
  264. q1.push_back(1);
  265. q1.clear();
  266. EXPECT_EQ (true, q1.empty());
  267. EXPECT_EQ (true, q2.full());
  268. EXPECT_EQ (8UL, q1.capacity());
  269. EXPECT_EQ (8UL, q2.capacity());
  270. EXPECT_EQ (0UL, q1.size());
  271. EXPECT_EQ (8UL, q2.size());
  272. q1.push_back(2);
  273. EXPECT_EQ (1UL, q1.size());
  274. q1.push_front(1);
  275. EXPECT_EQ (2UL, q1.size());
  276. q1.pop_back();
  277. EXPECT_EQ (1UL, q1.size());
  278. q1.pop_front();
  279. EXPECT_EQ (0UL, q1.size());
  280. }
  281. // push-pop limits
  282. TEST (Tdeque, push_pop_limits_atomic) {
  283. deque<int, 8, true> q1;
  284. deque<int, 8, true> q2{1, 2, 3, 4, 5, 6, 7, 8};
  285. EXPECT_EQ (int{}, q1.pop_back());
  286. EXPECT_EQ (0UL, q1.size());
  287. EXPECT_EQ (true, q1.empty());
  288. EXPECT_EQ (false, q1.full());
  289. EXPECT_EQ (int{}, q1.pop_front());
  290. EXPECT_EQ (0UL, q1.size());
  291. EXPECT_EQ (true, q1.empty());
  292. EXPECT_EQ (false, q1.full());
  293. q2.push_front(0);
  294. EXPECT_EQ (1, q2.front());
  295. EXPECT_EQ (8, q2.back());
  296. EXPECT_EQ (8UL, q2.size());
  297. EXPECT_EQ (false, q2.empty());
  298. EXPECT_EQ (true, q2.full());
  299. q2.push_back(9);
  300. EXPECT_EQ (1, q2.front());
  301. EXPECT_EQ (8, q2.back());
  302. EXPECT_EQ (8UL, q2.size());
  303. EXPECT_EQ (false, q2.empty());
  304. EXPECT_EQ (true, q2.full());
  305. }
  306. // iterators
  307. TEST (Tdeque, iterators_atomic) {
  308. deque<int, 8, true> q1{1, 2, 3, 4, 5, 6, 7, 8};
  309. int check_it=1;
  310. EXPECT_EQ (q1.begin().base(), q1.end().base());
  311. EXPECT_NE (q1.begin().iter(), q1.end().iter());
  312. EXPECT_EQ (1, *q1.begin());
  313. EXPECT_EQ (true, (q1.begin() == ++q1.end())); // loop edge iterators
  314. for (auto it = q1.begin() ; it != q1.end() ; ++it)
  315. EXPECT_EQ(*it, check_it++);
  316. EXPECT_EQ(9, check_it); // run through all
  317. EXPECT_EQ (1, q1.front()); // queue stays intact
  318. EXPECT_EQ (8, q1.back());
  319. EXPECT_EQ (8UL, q1.size());
  320. EXPECT_EQ (false, q1.empty());
  321. EXPECT_EQ (true, q1.full());
  322. q1.pop_front();
  323. q1.pop_back();
  324. check_it=2;
  325. for (auto& it : q1)
  326. EXPECT_EQ(it, check_it++);
  327. EXPECT_EQ(8, check_it); // run through all
  328. EXPECT_EQ (2, q1.front()); // queue stays intact
  329. EXPECT_EQ (7, q1.back());
  330. EXPECT_EQ (6UL, q1.size());
  331. EXPECT_EQ (false, q1.empty());
  332. EXPECT_EQ (false, q1.full());
  333. deque<int, 8, true> q2;
  334. q2.push_front(2);
  335. q2.push_front(1);
  336. q2.push_back(3);
  337. q2.push_back(4);
  338. q2.push_back(5);
  339. check_it =1;
  340. for (auto& it : q2)
  341. EXPECT_EQ(it, check_it++);
  342. EXPECT_EQ(6, check_it); // run through all
  343. }
  344. TEST (Tdeque, range_atomic) {
  345. deque<int, 8, true> q1{1, 2, 3, 4, 5, 6, 7, 8};
  346. int check_it=1;
  347. for (auto& it : q1.contents())
  348. EXPECT_EQ(it, check_it++);
  349. EXPECT_EQ(9, check_it); // run through all
  350. }
  351. TEST(Tdeque, race) {
  352. constexpr size_t N = 1000000;
  353. deque<int, N, true> q;
  354. int result[N];
  355. auto push_front = [&](){
  356. for (size_t i=1 ; i<=N ; ++i) q.push_front(i);
  357. };
  358. auto push_back = [&](){
  359. for (size_t i=1 ; i<=N ; ++i) q.push_back(i);
  360. };
  361. auto pop_front = [&](){
  362. for (size_t i=0 ; i<N ; ) {
  363. result[i] = q.pop_front();
  364. if (result[i] != int{})
  365. ++i;
  366. }
  367. };
  368. auto pop_back = [&](){
  369. for (size_t i=0 ; i<N ; ) {
  370. result[i] = q.pop_back();
  371. if (result[i] != int{})
  372. ++i;
  373. }
  374. };
  375. std::memset(result, 0, sizeof result);
  376. std::thread th1 (push_front);
  377. std::thread th2 (pop_back);
  378. th1.join();
  379. th2.join();
  380. for (size_t i=0 ; i<N ; ++i)
  381. EXPECT_EQ (result[i], (int)i+1);
  382. std::memset(result, 0, sizeof result);
  383. std::thread th3 (push_back);
  384. std::thread th4 (pop_front);
  385. th3.join();
  386. th4.join();
  387. for (size_t i=0 ; i<N ; ++i)
  388. EXPECT_EQ (result[i], (int)i+1);
  389. }
  390. }