/* * Copyright 2017-2024 The OpenSSL Project Authors. All Rights Reserved. * Copyright (c) 2017, Oracle and/or its affiliates. All rights reserved. * * Licensed under the Apache License 2.0 (the "License"). You may not use * this file except in compliance with the License. You can obtain a copy * in the file LICENSE in the source distribution or at * https://www.openssl.org/source/license.html */ #include #include #include #include #include #include #include #include #include "internal/nelem.h" #include "threadstest.h" #include "testutil.h" /* * The macros below generate unused functions which error out one of the clang * builds. We disable this check here. */ #ifdef __clang__ #pragma clang diagnostic ignored "-Wunused-function" #endif DEFINE_LHASH_OF_EX(int); static int int_tests[] = { 65537, 13, 1, 3, -5, 6, 7, 4, -10, -12, -14, 22, 9, -17, 16, 17, -23, 35, 37, 173, 11 }; static const size_t n_int_tests = OSSL_NELEM(int_tests); static short int_found[OSSL_NELEM(int_tests)]; static short int_not_found; static unsigned long int int_hash(const int *p) { return 3 & *p; /* To force collisions */ } static int int_cmp(const int *p, const int *q) { return *p != *q; } static int int_find(int n) { unsigned int i; for (i = 0; i < n_int_tests; i++) if (int_tests[i] == n) return i; return -1; } static void int_doall(int *v) { const int n = int_find(*v); if (n < 0) int_not_found++; else int_found[n]++; } static void int_doall_arg(int *p, short *f) { const int n = int_find(*p); if (n < 0) int_not_found++; else f[n]++; } IMPLEMENT_LHASH_DOALL_ARG(int, short); static int test_int_lhash(void) { static struct { int data; int null; } dels[] = { { 65537, 0 }, { 173, 0 }, { 999, 1 }, { 37, 0 }, { 1, 0 }, { 34, 1 } }; const unsigned int n_dels = OSSL_NELEM(dels); LHASH_OF(int) *h = lh_int_new(&int_hash, &int_cmp); unsigned int i; int testresult = 0, j, *p; if (!TEST_ptr(h)) goto end; /* insert */ for (i = 0; i < n_int_tests; i++) if (!TEST_ptr_null(lh_int_insert(h, int_tests + i))) { TEST_info("int insert %d", i); goto end; } /* num_items */ if (!TEST_int_eq((size_t)lh_int_num_items(h), n_int_tests)) goto end; /* retrieve */ for (i = 0; i < n_int_tests; i++) if (!TEST_int_eq(*lh_int_retrieve(h, int_tests + i), int_tests[i])) { TEST_info("lhash int retrieve value %d", i); goto end; } for (i = 0; i < n_int_tests; i++) if (!TEST_ptr_eq(lh_int_retrieve(h, int_tests + i), int_tests + i)) { TEST_info("lhash int retrieve address %d", i); goto end; } j = 1; if (!TEST_ptr_eq(lh_int_retrieve(h, &j), int_tests + 2)) goto end; /* replace */ j = 13; if (!TEST_ptr(p = lh_int_insert(h, &j))) goto end; if (!TEST_ptr_eq(p, int_tests + 1)) goto end; if (!TEST_ptr_eq(lh_int_retrieve(h, int_tests + 1), &j)) goto end; /* do_all */ memset(int_found, 0, sizeof(int_found)); int_not_found = 0; lh_int_doall(h, &int_doall); if (!TEST_int_eq(int_not_found, 0)) { TEST_info("lhash int doall encountered a not found condition"); goto end; } for (i = 0; i < n_int_tests; i++) if (!TEST_int_eq(int_found[i], 1)) { TEST_info("lhash int doall %d", i); goto end; } /* do_all_arg */ memset(int_found, 0, sizeof(int_found)); int_not_found = 0; lh_int_doall_short(h, int_doall_arg, int_found); if (!TEST_int_eq(int_not_found, 0)) { TEST_info("lhash int doall arg encountered a not found condition"); goto end; } for (i = 0; i < n_int_tests; i++) if (!TEST_int_eq(int_found[i], 1)) { TEST_info("lhash int doall arg %d", i); goto end; } /* delete */ for (i = 0; i < n_dels; i++) { const int b = lh_int_delete(h, &dels[i].data) == NULL; if (!TEST_int_eq(b ^ dels[i].null, 0)) { TEST_info("lhash int delete %d", i); goto end; } } /* error */ if (!TEST_int_eq(lh_int_error(h), 0)) goto end; testresult = 1; end: lh_int_free(h); return testresult; } static int int_filter_all(HT_VALUE *v, void *arg) { return 1; } HT_START_KEY_DEFN(intkey) HT_DEF_KEY_FIELD(mykey, int) HT_END_KEY_DEFN(INTKEY) IMPLEMENT_HT_VALUE_TYPE_FNS(int, test, static) static int int_foreach(HT_VALUE *v, void *arg) { int *vd = ossl_ht_test_int_from_value(v); const int n = int_find(*vd); if (n < 0) int_not_found++; else int_found[n]++; return 1; } static uint64_t hashtable_hash(uint8_t *key, size_t keylen) { return (uint64_t)(*(uint32_t *)key); } static int test_int_hashtable(void) { static struct { int data; int should_del; } dels[] = { { 65537 , 1}, { 173 , 1}, { 999 , 0 }, { 37 , 1 }, { 1 , 1 }, { 34 , 0 } }; const size_t n_dels = OSSL_NELEM(dels); HT_CONFIG hash_conf = { NULL, NULL, NULL, 0, 1, }; INTKEY key; int rc = 0; size_t i; HT *ht = NULL; int todel; HT_VALUE_LIST *list = NULL; ht = ossl_ht_new(&hash_conf); if (ht == NULL) return 0; /* insert */ HT_INIT_KEY(&key); for (i = 0; i < n_int_tests; i++) { HT_SET_KEY_FIELD(&key, mykey, int_tests[i]); if (!TEST_int_eq(ossl_ht_test_int_insert(ht, TO_HT_KEY(&key), &int_tests[i], NULL), 1)) { TEST_info("int insert %zu", i); goto end; } } /* num_items */ if (!TEST_int_eq((size_t)ossl_ht_count(ht), n_int_tests)) goto end; /* foreach, no arg */ memset(int_found, 0, sizeof(int_found)); int_not_found = 0; ossl_ht_foreach_until(ht, int_foreach, NULL); if (!TEST_int_eq(int_not_found, 0)) { TEST_info("hashtable int foreach encountered a not found condition"); goto end; } for (i = 0; i < n_int_tests; i++) if (!TEST_int_eq(int_found[i], 1)) { TEST_info("hashtable int foreach %zu", i); goto end; } /* filter */ list = ossl_ht_filter(ht, 64, int_filter_all, NULL); if (!TEST_int_eq((size_t)list->list_len, n_int_tests)) goto end; ossl_ht_value_list_free(list); /* delete */ for (i = 0; i < n_dels; i++) { HT_SET_KEY_FIELD(&key, mykey, dels[i].data); todel = ossl_ht_delete(ht, TO_HT_KEY(&key)); if (dels[i].should_del) { if (!TEST_int_eq(todel, 1)) { TEST_info("hashtable couldn't find entry %d to delete\n", dels[i].data); goto end; } } else { if (!TEST_int_eq(todel, 0)) { TEST_info("%d found an entry that shouldn't be there\n", dels[i].data); goto end; } } } rc = 1; end: ossl_ht_free(ht); return rc; } static unsigned long int stress_hash(const int *p) { return *p; } #ifdef MEASURE_HASH_PERFORMANCE static int timeval_subtract (struct timeval *result, struct timeval *x, struct timeval *y) { /* Perform the carry for the later subtraction by updating y. */ if (x->tv_usec < y->tv_usec) { int nsec = (y->tv_usec - x->tv_usec) / 1000000 + 1; y->tv_usec -= 1000000 * nsec; y->tv_sec += nsec; } if (x->tv_usec - y->tv_usec > 1000000) { int nsec = (x->tv_usec - y->tv_usec) / 1000000; y->tv_usec += 1000000 * nsec; y->tv_sec -= nsec; } /* * Compute the time remaining to wait. * tv_usec is certainly positive. */ result->tv_sec = x->tv_sec - y->tv_sec; result->tv_usec = x->tv_usec - y->tv_usec; /* Return 1 if result is negative. */ return x->tv_sec < y->tv_sec; } #endif static int test_stress(void) { LHASH_OF(int) *h = lh_int_new(&stress_hash, &int_cmp); const unsigned int n = 2500000; unsigned int i; int testresult = 0, *p; #ifdef MEASURE_HASH_PERFORMANCE struct timeval start, end, delta; #endif if (!TEST_ptr(h)) goto end; #ifdef MEASURE_HASH_PERFORMANCE gettimeofday(&start, NULL); #endif /* insert */ for (i = 0; i < n; i++) { p = OPENSSL_malloc(sizeof(i)); if (!TEST_ptr(p)) { TEST_info("lhash stress out of memory %d", i); goto end; } *p = 3 * i + 1; lh_int_insert(h, p); } /* num_items */ if (!TEST_int_eq(lh_int_num_items(h), n)) goto end; /* delete in a different order */ for (i = 0; i < n; i++) { const int j = (7 * i + 4) % n * 3 + 1; if (!TEST_ptr(p = lh_int_delete(h, &j))) { TEST_info("lhash stress delete %d\n", i); goto end; } if (!TEST_int_eq(*p, j)) { TEST_info("lhash stress bad value %d", i); goto end; } OPENSSL_free(p); } testresult = 1; end: #ifdef MEASURE_HASH_PERFORMANCE gettimeofday(&end, NULL); timeval_subtract(&delta, &end, &start); TEST_info("lhash stress runs in %ld.%ld seconds", delta.tv_sec, delta.tv_usec); #endif lh_int_free(h); return testresult; } static void hashtable_intfree(HT_VALUE *v) { OPENSSL_free(v->value); } static int test_hashtable_stress(int idx) { const unsigned int n = 2500000; unsigned int i; int testresult = 0, *p; HT_CONFIG hash_conf = { NULL, /* use default context */ hashtable_intfree, /* our free function */ hashtable_hash, /* our hash function */ 625000, /* preset hash size */ 1, /* Check collisions */ 0 /* Lockless reads */ }; HT *h; INTKEY key; HT_VALUE *v; #ifdef MEASURE_HASH_PERFORMANCE struct timeval start, end, delta; #endif hash_conf.lockless_reads = idx; h = ossl_ht_new(&hash_conf); if (!TEST_ptr(h)) goto end; #ifdef MEASURE_HASH_PERFORMANCE gettimeofday(&start, NULL); #endif HT_INIT_KEY(&key); /* insert */ for (i = 0; i < n; i++) { p = OPENSSL_malloc(sizeof(i)); if (!TEST_ptr(p)) { TEST_info("hashtable stress out of memory %d", i); goto end; } *p = 3 * i + 1; HT_SET_KEY_FIELD(&key, mykey, *p); if (!TEST_int_eq(ossl_ht_test_int_insert(h, TO_HT_KEY(&key), p, NULL), 1)) { TEST_info("hashtable unable to insert element %d\n", *p); goto end; } } /* make sure we stored everything */ if (!TEST_int_eq((size_t)ossl_ht_count(h), n)) goto end; /* delete or get in a different order */ for (i = 0; i < n; i++) { const int j = (7 * i + 4) % n * 3 + 1; HT_SET_KEY_FIELD(&key, mykey, j); switch (idx) { case 0: if (!TEST_int_eq((ossl_ht_delete(h, TO_HT_KEY(&key))), 1)) { TEST_info("hashtable didn't delete key %d\n", j); goto end; } break; case 1: if (!TEST_ptr(p = ossl_ht_test_int_get(h, TO_HT_KEY(&key), &v)) || !TEST_int_eq(*p, j)) { TEST_info("hashtable didn't get key %d\n", j); goto end; } break; } } testresult = 1; end: #ifdef MEASURE_HASH_PERFORMANCE gettimeofday(&end, NULL); timeval_subtract(&delta, &end, &start); TEST_info("hashtable stress runs in %ld.%ld seconds", delta.tv_sec, delta.tv_usec); #endif ossl_ht_free(h); return testresult; } typedef struct test_mt_entry { int in_table; int pending_delete; } TEST_MT_ENTRY; static HT *m_ht = NULL; #define TEST_MT_POOL_SZ 256 #define TEST_THREAD_ITERATIONS 10000 static struct test_mt_entry test_mt_entries[TEST_MT_POOL_SZ]; static char *worker_exits[4]; HT_START_KEY_DEFN(mtkey) HT_DEF_KEY_FIELD(index, unsigned int) HT_END_KEY_DEFN(MTKEY) IMPLEMENT_HT_VALUE_TYPE_FNS(TEST_MT_ENTRY, mt, static) static int worker_num = 0; static CRYPTO_RWLOCK *worker_lock; static int free_failure = 0; static int shutting_down = 0; static int global_iteration = 0; static void hashtable_mt_free(HT_VALUE *v) { TEST_MT_ENTRY *m = ossl_ht_mt_TEST_MT_ENTRY_from_value(v); int pending_delete; int ret; CRYPTO_atomic_load_int(&m->pending_delete, &pending_delete, worker_lock); if (shutting_down == 1) return; if (pending_delete == 0) { TEST_info("Freeing element which was not scheduled for free"); free_failure = 1; } else { CRYPTO_atomic_add(&m->pending_delete, -1, &ret, worker_lock); } } #define BEHAVIOR_MASK 0x3 #define DO_LOOKUP 0 #define DO_INSERT 1 #define DO_REPLACE 2 #define DO_DELETE 3 static void do_mt_hash_work(void) { MTKEY key; unsigned int index; int num; TEST_MT_ENTRY *m; TEST_MT_ENTRY *expected_m = NULL; HT_VALUE *v = NULL; TEST_MT_ENTRY **r = NULL; int expected_rc; int ret; char behavior; size_t iter = 0; int giter; CRYPTO_atomic_add(&worker_num, 1, &num, worker_lock); num--; /* atomic_add is an add/fetch operation */ HT_INIT_KEY(&key); for (iter = 0; iter < TEST_THREAD_ITERATIONS; iter++) { if (!RAND_bytes((unsigned char *)&index, sizeof(unsigned int))) { worker_exits[num] = "Failed to get random index"; return; } index %= TEST_MT_POOL_SZ; if (!RAND_bytes((unsigned char *)&behavior, sizeof(char))) { worker_exits[num] = "Failed to get random behavior"; return; } behavior &= BEHAVIOR_MASK; expected_m = &test_mt_entries[index]; HT_KEY_RESET(&key); HT_SET_KEY_FIELD(&key, index, index); if (!CRYPTO_atomic_add(&global_iteration, 1, &giter, worker_lock)) { worker_exits[num] = "Unable to increment global iterator"; return; } switch(behavior) { case DO_LOOKUP: ossl_ht_read_lock(m_ht); m = ossl_ht_mt_TEST_MT_ENTRY_get(m_ht, TO_HT_KEY(&key), &v); if (m != NULL && m != expected_m) { worker_exits[num] = "Read unexpected value from hashtable"; TEST_info("Iteration %d Read unexpected value %p when %p expected", giter, (void *)m, (void *)expected_m); } ossl_ht_read_unlock(m_ht); if (worker_exits[num] != NULL) return; break; case DO_INSERT: case DO_REPLACE: ossl_ht_write_lock(m_ht); if (behavior == DO_REPLACE) { expected_rc = 1; r = &m; } else { expected_rc = !expected_m->in_table; r = NULL; } if (expected_rc != ossl_ht_mt_TEST_MT_ENTRY_insert(m_ht, TO_HT_KEY(&key), expected_m, r)) { TEST_info("Iteration %d Expected rc %d on %s of element %d which is %s\n", giter, expected_rc, behavior == DO_REPLACE ? "replace" : "insert", index, expected_m->in_table ? "in table" : "not in table"); worker_exits[num] = "Failure on insert"; } if (expected_rc == 1) expected_m->in_table = 1; ossl_ht_write_unlock(m_ht); if (worker_exits[num] != NULL) return; break; case DO_DELETE: ossl_ht_write_lock(m_ht); expected_rc = expected_m->in_table; if (expected_rc != ossl_ht_delete(m_ht, TO_HT_KEY(&key))) { TEST_info("Iteration %d Expected rc %d on delete of element %d which is %s\n", giter, expected_rc, index, expected_m->in_table ? "in table" : "not in table"); worker_exits[num] = "Failure on delete"; } if (expected_rc == 1) { expected_m->in_table = 0; CRYPTO_atomic_add(&expected_m->pending_delete, 1, &ret, worker_lock); } ossl_ht_write_unlock(m_ht); if (worker_exits[num] != NULL) return; break; default: worker_exits[num] = "Undefined behavior specified"; return; } } } static int test_hashtable_multithread(void) { HT_CONFIG hash_conf = { NULL, /* use default context */ hashtable_mt_free, /* our free function */ NULL, /* default hash function */ 0, /* default hash size */ 1, /* Check collisions */ }; int ret = 0; thread_t workers[4]; int i; #ifdef MEASURE_HASH_PERFORMANCE struct timeval start, end, delta; #endif memset(worker_exits, 0, sizeof(char *) * 4); memset(test_mt_entries, 0, sizeof(TEST_MT_ENTRY) * TEST_MT_POOL_SZ); memset(workers, 0, sizeof(thread_t) * 4); m_ht = ossl_ht_new(&hash_conf); if (!TEST_ptr(m_ht)) goto end; worker_lock = CRYPTO_THREAD_lock_new(); if (worker_lock == NULL) goto end_free; #ifdef MEASURE_HASH_PERFORMANCE gettimeofday(&start, NULL); #endif for (i = 0; i < 4; i++) { if (!run_thread(&workers[i], do_mt_hash_work)) goto shutdown; } shutdown: for (--i; i >= 0; i--) { wait_for_thread(workers[i]); } /* * Now that the workers are done, check for any error * conditions */ ret = 1; for (i = 0; i < 4; i++) { if (worker_exits[i] != NULL) { TEST_info("Worker %d failed: %s\n", i, worker_exits[i]); ret = 0; } } if (free_failure == 1) { TEST_info("Encountered a free failure"); ret = 0; } #ifdef MEASURE_HASH_PERFORMANCE gettimeofday(&end, NULL); timeval_subtract(&delta, &end, &start); TEST_info("multithread stress runs 40000 ops in %ld.%ld seconds", delta.tv_sec, delta.tv_usec); #endif end_free: shutting_down = 1; ossl_ht_free(m_ht); end: return ret; } int setup_tests(void) { ADD_TEST(test_int_lhash); ADD_TEST(test_stress); ADD_TEST(test_int_hashtable); ADD_ALL_TESTS(test_hashtable_stress, 2); ADD_TEST(test_hashtable_multithread); return 1; }