/* Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. * The ASF licenses this file to You 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 "testutil.h" #include "fspr_strings.h" #include "fspr_thread_proc.h" #include "fspr_errno.h" #include "fspr_general.h" #include "fspr_atomic.h" #include "fspr_time.h" /* Use pthread_setconcurrency where it is available and not a nullop, * i.e. platforms using M:N or M:1 thread models: */ #if APR_HAS_THREADS && \ ((defined(SOLARIS2) && SOLARIS2 > 26) || defined(_AIX)) /* also HP-UX, IRIX? ... */ #define HAVE_PTHREAD_SETCONCURRENCY #endif #ifdef HAVE_PTHREAD_SETCONCURRENCY #include #endif static void test_init(abts_case *tc, void *data) { APR_ASSERT_SUCCESS(tc, "Could not initliaze atomics", fspr_atomic_init(p)); } static void test_set32(abts_case *tc, void *data) { fspr_uint32_t y32; fspr_atomic_set32(&y32, 2); ABTS_INT_EQUAL(tc, 2, y32); } static void test_read32(abts_case *tc, void *data) { fspr_uint32_t y32; fspr_atomic_set32(&y32, 2); ABTS_INT_EQUAL(tc, 2, fspr_atomic_read32(&y32)); } static void test_dec32(abts_case *tc, void *data) { fspr_uint32_t y32; int rv; fspr_atomic_set32(&y32, 2); rv = fspr_atomic_dec32(&y32); ABTS_INT_EQUAL(tc, 1, y32); ABTS_ASSERT(tc, "atomic_dec returned zero when it shouldn't", rv != 0); rv = fspr_atomic_dec32(&y32); ABTS_INT_EQUAL(tc, 0, y32); ABTS_ASSERT(tc, "atomic_dec didn't returned zero when it should", rv == 0); } static void test_xchg32(abts_case *tc, void *data) { fspr_uint32_t oldval; fspr_uint32_t y32; fspr_atomic_set32(&y32, 100); oldval = fspr_atomic_xchg32(&y32, 50); ABTS_INT_EQUAL(tc, 100, oldval); ABTS_INT_EQUAL(tc, 50, y32); } static void test_cas_equal(abts_case *tc, void *data) { fspr_uint32_t casval = 0; fspr_uint32_t oldval; oldval = fspr_atomic_cas32(&casval, 12, 0); ABTS_INT_EQUAL(tc, 0, oldval); ABTS_INT_EQUAL(tc, 12, casval); } static void test_cas_equal_nonnull(abts_case *tc, void *data) { fspr_uint32_t casval = 12; fspr_uint32_t oldval; oldval = fspr_atomic_cas32(&casval, 23, 12); ABTS_INT_EQUAL(tc, 12, oldval); ABTS_INT_EQUAL(tc, 23, casval); } static void test_cas_notequal(abts_case *tc, void *data) { fspr_uint32_t casval = 12; fspr_uint32_t oldval; oldval = fspr_atomic_cas32(&casval, 23, 2); ABTS_INT_EQUAL(tc, 12, oldval); ABTS_INT_EQUAL(tc, 12, casval); } static void test_add32(abts_case *tc, void *data) { fspr_uint32_t oldval; fspr_uint32_t y32; fspr_atomic_set32(&y32, 23); oldval = fspr_atomic_add32(&y32, 4); ABTS_INT_EQUAL(tc, 23, oldval); ABTS_INT_EQUAL(tc, 27, y32); } static void test_inc32(abts_case *tc, void *data) { fspr_uint32_t oldval; fspr_uint32_t y32; fspr_atomic_set32(&y32, 23); oldval = fspr_atomic_inc32(&y32); ABTS_INT_EQUAL(tc, 23, oldval); ABTS_INT_EQUAL(tc, 24, y32); } static void test_set_add_inc_sub(abts_case *tc, void *data) { fspr_uint32_t y32; fspr_atomic_set32(&y32, 0); fspr_atomic_add32(&y32, 20); fspr_atomic_inc32(&y32); fspr_atomic_sub32(&y32, 10); ABTS_INT_EQUAL(tc, 11, y32); } static void test_wrap_zero(abts_case *tc, void *data) { fspr_uint32_t y32; fspr_uint32_t rv; fspr_uint32_t minus1 = -1; char *str; fspr_atomic_set32(&y32, 0); rv = fspr_atomic_dec32(&y32); ABTS_ASSERT(tc, "fspr_atomic_dec32 on zero returned zero.", rv != 0); str = fspr_psprintf(p, "zero wrap failed: 0 - 1 = %d", y32); ABTS_ASSERT(tc, str, y32 == minus1); } static void test_inc_neg1(abts_case *tc, void *data) { fspr_uint32_t y32 = -1; fspr_uint32_t minus1 = -1; fspr_uint32_t rv; char *str; rv = fspr_atomic_inc32(&y32); ABTS_ASSERT(tc, "fspr_atomic_dec32 on zero returned zero.", rv == minus1); str = fspr_psprintf(p, "zero wrap failed: -1 + 1 = %d", y32); ABTS_ASSERT(tc, str, y32 == 0); } #if APR_HAS_THREADS void * APR_THREAD_FUNC thread_func_mutex(fspr_thread_t *thd, void *data); void * APR_THREAD_FUNC thread_func_atomic(fspr_thread_t *thd, void *data); void * APR_THREAD_FUNC thread_func_none(fspr_thread_t *thd, void *data); fspr_thread_mutex_t *thread_lock; volatile fspr_uint32_t x = 0; /* mutex locks */ volatile fspr_uint32_t y = 0; /* atomic operations */ volatile fspr_uint32_t z = 0; /* no locks */ fspr_status_t exit_ret_val = 123; /* just some made up number to check on later */ #define NUM_THREADS 40 #define NUM_ITERATIONS 20000 void * APR_THREAD_FUNC thread_func_mutex(fspr_thread_t *thd, void *data) { int i; for (i = 0; i < NUM_ITERATIONS; i++) { fspr_thread_mutex_lock(thread_lock); x++; fspr_thread_mutex_unlock(thread_lock); } fspr_thread_exit(thd, exit_ret_val); return NULL; } void * APR_THREAD_FUNC thread_func_atomic(fspr_thread_t *thd, void *data) { int i; for (i = 0; i < NUM_ITERATIONS ; i++) { fspr_atomic_inc32(&y); fspr_atomic_add32(&y, 2); fspr_atomic_dec32(&y); fspr_atomic_dec32(&y); } fspr_thread_exit(thd, exit_ret_val); return NULL; } void * APR_THREAD_FUNC thread_func_none(fspr_thread_t *thd, void *data) { int i; for (i = 0; i < NUM_ITERATIONS ; i++) { z++; } fspr_thread_exit(thd, exit_ret_val); return NULL; } static void test_atomics_threaded(abts_case *tc, void *data) { fspr_thread_t *t1[NUM_THREADS]; fspr_thread_t *t2[NUM_THREADS]; fspr_thread_t *t3[NUM_THREADS]; fspr_status_t s1[NUM_THREADS]; fspr_status_t s2[NUM_THREADS]; fspr_status_t s3[NUM_THREADS]; fspr_status_t rv; int i; #ifdef HAVE_PTHREAD_SETCONCURRENCY pthread_setconcurrency(8); #endif rv = fspr_thread_mutex_create(&thread_lock, APR_THREAD_MUTEX_DEFAULT, p); APR_ASSERT_SUCCESS(tc, "Could not create lock", rv); for (i = 0; i < NUM_THREADS; i++) { fspr_status_t r1, r2, r3; r1 = fspr_thread_create(&t1[i], NULL, thread_func_mutex, NULL, p); r2 = fspr_thread_create(&t2[i], NULL, thread_func_atomic, NULL, p); r3 = fspr_thread_create(&t3[i], NULL, thread_func_none, NULL, p); ABTS_ASSERT(tc, "Failed creating threads", r1 == APR_SUCCESS && r2 == APR_SUCCESS && r3 == APR_SUCCESS); } for (i = 0; i < NUM_THREADS; i++) { fspr_thread_join(&s1[i], t1[i]); fspr_thread_join(&s2[i], t2[i]); fspr_thread_join(&s3[i], t3[i]); ABTS_ASSERT(tc, "Invalid return value from thread_join", s1[i] == exit_ret_val && s2[i] == exit_ret_val && s3[i] == exit_ret_val); } ABTS_INT_EQUAL(tc, x, NUM_THREADS * NUM_ITERATIONS); ABTS_INT_EQUAL(tc, fspr_atomic_read32(&y), NUM_THREADS * NUM_ITERATIONS); /* Comment out this test, because I have no clue what this test is * actually telling us. We are checking something that may or may not * be true, and it isn't really testing APR at all. ABTS_ASSERT(tc, "We expect this to fail, because we tried to update " "an integer in a non-thread-safe manner.", z != NUM_THREADS * NUM_ITERATIONS); */ } #endif /* !APR_HAS_THREADS */ abts_suite *testatomic(abts_suite *suite) { suite = ADD_SUITE(suite) abts_run_test(suite, test_init, NULL); abts_run_test(suite, test_set32, NULL); abts_run_test(suite, test_read32, NULL); abts_run_test(suite, test_dec32, NULL); abts_run_test(suite, test_xchg32, NULL); abts_run_test(suite, test_cas_equal, NULL); abts_run_test(suite, test_cas_equal_nonnull, NULL); abts_run_test(suite, test_cas_notequal, NULL); abts_run_test(suite, test_add32, NULL); abts_run_test(suite, test_inc32, NULL); abts_run_test(suite, test_set_add_inc_sub, NULL); abts_run_test(suite, test_wrap_zero, NULL); abts_run_test(suite, test_inc_neg1, NULL); #if APR_HAS_THREADS abts_run_test(suite, test_atomics_threaded, NULL); #endif return suite; }