/* * Copyright (c) 2009-2011 Red Hat, Inc. * * All rights reserved. * * Author: Jan Friesse (jfriesse@redhat.com) * * This software licensed under BSD license, the text of which follows: * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * - Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * - 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. * - Neither the name of the Red Hat, Inc. nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. * * 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 OWNER 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. */ /* * Provides test of SAM API */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include extern const char *__progname; static int test2_sig_delivered = 0; static int test5_hc_cb_count = 0; static int test6_sig_delivered = 0; /* * First test will just register SAM, with policy restart. First instance will * sleep one second, send hc and sleep another 3 seconds. This should force restart. * Second instance will sleep one second, send hc, stop hc and sleep 3 seconds. * Then start hc again and sleep 3 seconds. This should force restart again. * Last instance just calls initialize again. This should end with error. * Then call start, followed by stop and start again. Finally, we will call finalize * twice. One should succeed, second should fail. After this, we will call every function * (none should succeed). */ static int test1 (void) { cs_error_t error; unsigned int instance_id; int i; printf ("%s: initialize\n", __FUNCTION__); error = sam_initialize (2000, SAM_RECOVERY_POLICY_RESTART); if (error != CS_OK) { fprintf (stderr, "Can't initialize SAM API. Error %d\n", error); return 1; } printf ("%s: register\n", __FUNCTION__); error = sam_register (&instance_id); if (error != CS_OK) { fprintf (stderr, "Can't register. Error %d\n", error); return 1; } if (instance_id == 1 || instance_id == 2) { printf ("%s iid %d: start\n", __FUNCTION__, instance_id); error = sam_start (); if (error != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", error); return 1; } for (i = 0; i < 10; i++) { printf ("%s iid %d: sleep 1\n", __FUNCTION__, instance_id); sleep (1); printf ("%s iid %d: hc send\n", __FUNCTION__, instance_id); error = sam_hc_send (); if (error != CS_OK) { fprintf (stderr, "Can't send hc. Error %d\n", error); return 1; } } if (instance_id == 2) { printf ("%s iid %d: stop\n", __FUNCTION__, instance_id); error = sam_stop (); if (error != CS_OK) { fprintf (stderr, "Can't send hc. Error %d\n", error); return 1; } } printf ("%s iid %d: sleep 3\n", __FUNCTION__, instance_id); sleep (3); printf ("%s iid %d: start\n", __FUNCTION__, instance_id); error = sam_start (); if (error != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", error); return 1; } printf ("%s iid %d: sleep 3\n", __FUNCTION__, instance_id); sleep (3); return 0; } if (instance_id == 3) { error = sam_initialize (2000, SAM_RECOVERY_POLICY_RESTART); if (error == CS_OK) { fprintf (stderr, "Can initialize SAM API after initialization"); return 1; } error = sam_start (); if (error != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", error); return 1; } error = sam_stop (); if (error != CS_OK) { fprintf (stderr, "Can't stop hc. Error %d\n", error); return 1; } error = sam_finalize (); if (error != CS_OK) { fprintf (stderr, "Can't finalize sam. Error %d\n", error); return 1; } error = sam_finalize (); if (error == CS_OK) { fprintf (stderr, "Can finalize sam after finalization!\n"); return 1; } if (sam_initialize (2, SAM_RECOVERY_POLICY_RESTART) == CS_OK || sam_start () == CS_OK || sam_stop () == CS_OK || sam_register (NULL) == CS_OK || sam_hc_send () == CS_OK || sam_hc_callback_register (NULL) == CS_OK) { fprintf (stderr, "Can call one of function after finalization!\n"); return 1; } return 0; } return 1; } static void test2_signal (int sig) { printf ("%s\n", __FUNCTION__); test2_sig_delivered = 1; } /* * This tests recovery policy quit and callback. */ static int test2 (void) { cs_error_t error; unsigned int instance_id; printf ("%s: initialize\n", __FUNCTION__); error = sam_initialize (2000, SAM_RECOVERY_POLICY_QUIT); if (error != CS_OK) { fprintf (stderr, "Can't initialize SAM API. Error %d\n", error); return 1; } printf ("%s: register\n", __FUNCTION__); error = sam_register (&instance_id); if (error != CS_OK) { fprintf (stderr, "Can't register. Error %d\n", error); return 1; } if (instance_id == 1) { signal (SIGTERM, test2_signal); printf ("%s iid %d: start\n", __FUNCTION__, instance_id); error = sam_start (); if (error != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", error); return 1; } printf ("%s iid %d: sleep 1\n", __FUNCTION__, instance_id); sleep (1); printf ("%s iid %d: hc send\n", __FUNCTION__, instance_id); error = sam_hc_send (); if (error != CS_OK) { fprintf (stderr, "Can't send hc. Error %d\n", error); return 1; } printf ("%s iid %d: wait for delivery of signal\n", __FUNCTION__, instance_id); while (!test2_sig_delivered) { sleep (1); } printf ("%s iid %d: wait for real kill\n", __FUNCTION__, instance_id); sleep (3); } return 1; } /* * Smoke test. Better to turn off coredump ;) This has no time limit, just restart process * when it dies. */ static int test3 (void) { cs_error_t error; unsigned int instance_id; printf ("%s: initialize\n", __FUNCTION__); error = sam_initialize (0, SAM_RECOVERY_POLICY_RESTART); if (error != CS_OK) { fprintf (stderr, "Can't initialize SAM API. Error %d\n", error); return 1; } printf ("%s: register\n", __FUNCTION__); error = sam_register (&instance_id); if (error != CS_OK) { fprintf (stderr, "Can't register. Error %d\n", error); return 1; } if (instance_id < 100) { printf ("%s iid %d: start\n", __FUNCTION__, instance_id); error = sam_start (); if (error != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", error); return 1; } printf ("%s iid %d: Sending signal\n", __FUNCTION__, instance_id); kill(getpid(), SIGSEGV); return 1; } return 0; } /* * Test sam_data_store, sam_data_restore and sam_data_getsize */ static int test4 (void) { size_t size; cs_error_t err; int i; unsigned int instance_id; char saved_data[128]; char saved_data2[128]; printf ("%s: sam_data_getsize 1\n", __FUNCTION__); err = sam_data_getsize (&size); if (err != CS_ERR_BAD_HANDLE) { fprintf (stderr, "Test should return CS_ERR_BAD_HANDLE. Error returned %d\n", err); return 1; } printf ("%s: sam_data_getsize 2\n", __FUNCTION__); err = sam_data_getsize (NULL); if (err != CS_ERR_INVALID_PARAM) { fprintf (stderr, "Test should return CS_ERR_INVALID_PARAM. Error returned %d\n", err); return 1; } printf ("%s: sam_data_store 1\n", __FUNCTION__); err = sam_data_store (NULL, 0); if (err != CS_ERR_BAD_HANDLE) { fprintf (stderr, "Test should return CS_ERR_BAD_HANDLE. Error returned %d\n", err); return 1; } printf ("%s: sam_data_restore 1\n", __FUNCTION__); err = sam_data_restore (saved_data, sizeof (saved_data)); if (err != CS_ERR_BAD_HANDLE) { fprintf (stderr, "Test should return CS_ERR_BAD_HANDLE. Error returned %d\n", err); return 1; } printf ("%s: sam_initialize\n", __FUNCTION__); err = sam_initialize (0, SAM_RECOVERY_POLICY_RESTART); if (err != CS_OK) { fprintf (stderr, "Can't initialize SAM API. Error %d\n", err); return 1; } printf ("%s: sam_data_getsize 3\n", __FUNCTION__); err = sam_data_getsize (&size); if (err != CS_OK) { fprintf (stderr, "Test should return CS_ERR_BAD_HANDLE. Error returned %d\n", err); return 1; } if (size != 0) { fprintf (stderr, "Test should return size of 0. Returned %zx\n", size); return 1; } printf ("%s: sam_data_restore 2\n", __FUNCTION__); err = sam_data_restore (NULL, sizeof (saved_data)); if (err != CS_ERR_INVALID_PARAM) { fprintf (stderr, "Test should return CS_ERR_INVALID_PARAM. Error returned %d\n", err); return 1; } /* * Store some real data */ for (i = 0; i < sizeof (saved_data); i++) { saved_data[i] = (char)(i + 5); } printf ("%s: sam_data_store 2\n", __FUNCTION__); err = sam_data_store (saved_data, sizeof (saved_data)); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } printf ("%s: sam_data_getsize 4\n", __FUNCTION__); err = sam_data_getsize (&size); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } if (size != sizeof (saved_data)) { fprintf (stderr, "Test should return size of 0. Returned %zx\n", size); return 1; } printf ("%s: sam_data_restore 3\n", __FUNCTION__); err = sam_data_restore (saved_data2, sizeof (saved_data2) - 1); if (err != CS_ERR_INVALID_PARAM) { fprintf (stderr, "Test should return CS_ERR_INVALID_PARAM. Error returned %d\n", err); return 1; } printf ("%s: sam_data_restore 4\n", __FUNCTION__); err = sam_data_restore (saved_data2, sizeof (saved_data2)); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } if (memcmp (saved_data, saved_data2, sizeof (saved_data2)) != 0) { fprintf (stderr, "Retored data are not same\n"); return 1; } memset (saved_data2, 0, sizeof (saved_data2)); printf ("%s: sam_data_store 3\n", __FUNCTION__); err = sam_data_store (NULL, 1); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } printf ("%s: sam_data_getsize 5\n", __FUNCTION__); err = sam_data_getsize (&size); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } if (size != 0) { fprintf (stderr, "Test should return size of 0. Returned %zx\n", size); return 1; } printf ("%s: sam_data_store 4\n", __FUNCTION__); err = sam_data_store (saved_data, sizeof (saved_data)); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } printf ("%s: register\n", __FUNCTION__); err = sam_register (&instance_id); if (err != CS_OK) { fprintf (stderr, "Can't register. Error %d\n", err); return 1; } if (instance_id == 1) { printf ("%s iid %d: sam_start\n", __FUNCTION__, instance_id); err = sam_start (); if (err != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", err); return 1; } printf ("%s iid %d: sam_data_getsize 6\n", __FUNCTION__, instance_id); err = sam_data_getsize (&size); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } if (size != sizeof (saved_data2)) { fprintf (stderr, "Test should return size of 0. Returned %zx\n", size); return 1; } printf ("%s iid %d: sam_data_restore 5\n", __FUNCTION__, instance_id); err = sam_data_restore (saved_data2, sizeof (saved_data2)); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } if (memcmp (saved_data, saved_data2, sizeof (saved_data2)) != 0) { fprintf (stderr, "Retored data are not same\n"); return 1; } for (i = 0; i < sizeof (saved_data); i++) { saved_data[i] = (char)(i - 5); } printf ("%s iid %d: sam_data_store 5\n", __FUNCTION__, instance_id); err = sam_data_store (saved_data, sizeof (saved_data) - 7); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } exit (1); } if (instance_id == 2) { printf ("%s iid %d: sam_start\n", __FUNCTION__, instance_id); err = sam_start (); if (err != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", err); return 1; } printf ("%s iid %d: sam_data_getsize 7\n", __FUNCTION__, instance_id); err = sam_data_getsize (&size); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } if (size != sizeof (saved_data2) - 7) { fprintf (stderr, "Test should return size of 0. Returned %zx\n", size); return 1; } printf ("%s iid %d: sam_data_restore 6\n", __FUNCTION__, instance_id); err = sam_data_restore (saved_data2, sizeof (saved_data2)); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } for (i = 0; i < sizeof (saved_data); i++) { saved_data[i] = (char)(i - 5); } if (memcmp (saved_data, saved_data2, sizeof (saved_data2) - 7) != 0) { fprintf (stderr, "Retored data are not same\n"); return 1; } printf ("%s iid %d: sam_data_store 6\n", __FUNCTION__, instance_id); err = sam_data_store (NULL, 0); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } exit (1); } if (instance_id == 3) { printf ("%s iid %d: sam_data_getsize 8\n", __FUNCTION__, instance_id); err = sam_data_getsize (&size); if (err != CS_OK) { fprintf (stderr, "Test should return CS_OK. Error returned %d\n", err); return 1; } if (size != 0) { fprintf (stderr, "Test should return size of 0. Returned %zx\n", size); return 1; } } return (0); } static int test5_hc_cb (void) { cs_error_t res; printf ("%s %d\n", __FUNCTION__, ++test5_hc_cb_count); res = sam_data_store (&test5_hc_cb_count, sizeof (test5_hc_cb_count)); if (res != CS_OK) return 1; if (test5_hc_cb_count > 10) return 1; return 0; } /* * Test event driven healtchecking. */ static int test5 (void) { cs_error_t error; unsigned int instance_id; int hc_cb_count; printf ("%s: initialize\n", __FUNCTION__); error = sam_initialize (100, SAM_RECOVERY_POLICY_RESTART); if (error != CS_OK) { fprintf (stderr, "Can't initialize SAM API. Error %d\n", error); return 1; } printf ("%s: register\n", __FUNCTION__); error = sam_register (&instance_id); if (error != CS_OK) { fprintf (stderr, "Can't register. Error %d\n", error); return 1; } if (instance_id == 1) { printf ("%s iid %d: hc callback register\n", __FUNCTION__, instance_id); error = sam_hc_callback_register (test5_hc_cb); if (error != CS_OK) { fprintf (stderr, "Can't register hc cb. Error %d\n", error); return 1; } printf ("%s iid %d: start\n", __FUNCTION__, instance_id); error = sam_start (); if (error != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", error); return 1; } sleep (2); printf ("%s iid %d: Failed. Wasn't killed.\n", __FUNCTION__, instance_id); return 1; } if (instance_id == 2) { error = sam_data_restore (&hc_cb_count, sizeof (hc_cb_count)); if (error != CS_OK) { fprintf (stderr, "sam_data_restore should return CS_OK. Error returned %d\n", error); return 1; } if (hc_cb_count != 11) { fprintf (stderr, "%s iid %d: Premature killed. hc_cb_count should be 11 and it is %d\n", __FUNCTION__, instance_id - 1, hc_cb_count); return 1; } return 0; } return 1; } static void test6_signal (int sig) { cs_error_t error; printf ("%s\n", __FUNCTION__); test6_sig_delivered++; if ((error = sam_data_store (&test6_sig_delivered, sizeof (test6_sig_delivered))) != CS_OK) { fprintf (stderr, "Can't store data! Error : %d\n", error); } } /* * Test warn signal set. */ static int test6 (void) { cs_error_t error; unsigned int instance_id; int test6_sig_del; printf ("%s: initialize\n", __FUNCTION__); error = sam_initialize (2000, SAM_RECOVERY_POLICY_RESTART); if (error != CS_OK) { fprintf (stderr, "Can't initialize SAM API. Error %d\n", error); return 1; } printf ("%s: register\n", __FUNCTION__); error = sam_register (&instance_id); if (error != CS_OK) { fprintf (stderr, "Can't register. Error %d\n", error); return 1; } if (instance_id == 1) { error = sam_warn_signal_set (SIGUSR1); if (error != CS_OK) { fprintf (stderr, "Can't set warn signal. Error %d\n", error); return 1; } signal (SIGUSR1, test6_signal); printf ("%s iid %d: start\n", __FUNCTION__, instance_id); error = sam_start (); if (error != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", error); return 1; } printf ("%s iid %d: sleep 1\n", __FUNCTION__, instance_id); sleep (1); printf ("%s iid %d: hc send\n", __FUNCTION__, instance_id); error = sam_hc_send (); if (error != CS_OK) { fprintf (stderr, "Can't send hc. Error %d\n", error); return 1; } printf ("%s iid %d: wait for delivery of signal\n", __FUNCTION__, instance_id); while (!test6_sig_delivered) { sleep (1); } printf ("%s iid %d: wait for real kill\n", __FUNCTION__, instance_id); sleep (3); printf ("%s iid %d: wasn't killed\n", __FUNCTION__, instance_id); return (1); } if (instance_id == 2) { error = sam_data_restore (&test6_sig_del, sizeof (test6_sig_del)); if (error != CS_OK) { fprintf (stderr, "Can't restore data. Error %d\n", error); return 1; } if (test6_sig_del != 1) { fprintf (stderr, "Previous test failed. Signal was not delivered\n"); return 1; } error = sam_warn_signal_set (SIGKILL); if (error != CS_OK) { fprintf (stderr, "Can't set warn signal. Error %d\n", error); return 1; } signal (SIGUSR1, test6_signal); printf ("%s iid %d: start\n", __FUNCTION__, instance_id); error = sam_start (); if (error != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", error); return 1; } printf ("%s iid %d: sleep 1\n", __FUNCTION__, instance_id); sleep (1); printf ("%s iid %d: hc send\n", __FUNCTION__, instance_id); error = sam_hc_send (); if (error != CS_OK) { fprintf (stderr, "Can't send hc. Error %d\n", error); return 1; } printf ("%s iid %d: wait for delivery of signal\n", __FUNCTION__, instance_id); while (!test6_sig_delivered) { sleep (1); } printf ("%s iid %d: wasn't killed\n", __FUNCTION__, instance_id); return (1); } if (instance_id == 3) { error = sam_data_restore (&test6_sig_del, sizeof (test6_sig_del)); if (error != CS_OK) { fprintf (stderr, "Can't restore data. Error %d\n", error); return 1; } if (test6_sig_del != 1) { fprintf (stderr, "Previous test failed. Signal WAS delivered\n"); return 1; } return (0); } return 1; } static void *test7_thread (void *arg) { /* Wait 5s */ sleep (5); exit (0); } /* * Test quorum */ static int test7 (void) { cmap_handle_t cmap_handle; cs_error_t err; unsigned int instance_id; pthread_t kill_thread; char *str; err = cmap_initialize (&cmap_handle); if (err != CS_OK) { printf ("Could not initialize Cluster Map API instance error %d. Test skipped\n", err); return (1); } if (cmap_get_string(cmap_handle, "quorum.provider", &str) != CS_OK) { printf ("Could not get \"provider\" key: %d. Test skipped\n", err); return (1); } if (strcmp(str, "testquorum") != 0) { printf ("Provider is not testquorum. Test skipped\n"); free(str); return (1); } free(str); /* * Set to not quorate */ err = cmap_set_uint8(cmap_handle, "quorum.quorate", 0); if (err != CS_OK) { printf ("Can't set map key. Error %d\n", err); return (2); } printf ("%s: initialize\n", __FUNCTION__); err = sam_initialize (2000, SAM_RECOVERY_POLICY_QUORUM_RESTART); if (err != CS_OK) { fprintf (stderr, "Can't initialize SAM API. Error %d\n", err); return 2; } printf ("%s: register\n", __FUNCTION__); err = sam_register (&instance_id); if (err != CS_OK) { fprintf (stderr, "Can't register. Error %d\n", err); return 2; } if (instance_id == 1) { /* * Sam start should block forever, but 10s for us should be enough */ pthread_create (&kill_thread, NULL, test7_thread, NULL); printf ("%s iid %d: start - should block forever (waiting 5s)\n", __FUNCTION__, instance_id); err = sam_start (); if (err != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", err); return 2; } printf ("%s iid %d: wasn't killed\n", __FUNCTION__, instance_id); return (2); } if (instance_id == 2) { /* * Set to quorate */ err = cmap_set_uint8(cmap_handle, "quorum.quorate", 1); if (err != CS_OK) { printf ("Can't set map key. Error %d\n", err); return (2); } printf ("%s iid %d: start\n", __FUNCTION__, instance_id); err = sam_start (); if (err != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", err); return 2; } /* * Set corosync unquorate */ err = cmap_set_uint8(cmap_handle, "quorum.quorate", 0); if (err != CS_OK) { printf ("Can't set map key. Error %d\n", err); return (2); } printf ("%s iid %d: sleep 3\n", __FUNCTION__, instance_id); sleep (3); printf ("%s iid %d: wasn't killed\n", __FUNCTION__, instance_id); return (2); } if (instance_id == 3) { return (0); } return (2); } /* * Test cmap integration + quit policy */ static int test8 (pid_t pid, pid_t old_pid, int test_n) { cmap_handle_t cmap_handle; cs_error_t err; uint64_t tstamp1, tstamp2; int32_t msec_diff; unsigned int instance_id; char key_name[CMAP_KEYNAME_MAXLEN]; char *str; err = cmap_initialize (&cmap_handle); if (err != CS_OK) { printf ("Could not initialize Cluster Map API instance error %d. Test skipped\n", err); return (1); } printf ("%s test %d\n", __FUNCTION__, test_n); if (test_n == 2) { /* * Object should not exist */ printf ("%s Testing if object exists (it shouldn't)\n", __FUNCTION__); snprintf(key_name, CMAP_KEYNAME_MAXLEN, "resources.process.%d.state", pid); err = cmap_get_string(cmap_handle, key_name, &str); if (err == CS_OK) { printf ("Could find key \"%s\": %d.\n", key_name, err); free(str); return (2); } } if (test_n == 1 || test_n == 2) { printf ("%s: initialize\n", __FUNCTION__); err = sam_initialize (2000, SAM_RECOVERY_POLICY_QUIT | SAM_RECOVERY_POLICY_CMAP); if (err != CS_OK) { fprintf (stderr, "Can't initialize SAM API. Error %d\n", err); return 2; } printf ("%s: register\n", __FUNCTION__); err = sam_register (&instance_id); if (err != CS_OK) { fprintf (stderr, "Can't register. Error %d\n", err); return 2; } snprintf(key_name, CMAP_KEYNAME_MAXLEN, "resources.process.%d.recovery", pid); err = cmap_get_string(cmap_handle, key_name, &str); if (err != CS_OK) { printf ("Could not get \"recovery\" key: %d.\n", err); return (2); } if (strcmp(str, "quit") != 0) { printf ("Recovery key \"%s\" is not \"quit\".\n", key_name); free(str); return (2); } free(str); snprintf(key_name, CMAP_KEYNAME_MAXLEN, "resources.process.%d.state", pid); err = cmap_get_string(cmap_handle, key_name, &str); if (err != CS_OK) { printf ("Could not get \"state\" key: %d.\n", err); return (2); } if (strcmp(str, "stopped") != 0) { printf ("State key is not \"stopped\".\n"); free(str); return (2); } free(str); printf ("%s iid %d: start\n", __FUNCTION__, instance_id); err = sam_start (); if (err != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", err); return 2; } err = cmap_get_string(cmap_handle, key_name, &str); if (err != CS_OK) { printf ("Could not get \"state\" key: %d.\n", err); return (2); } if (strcmp(str, "running") != 0) { printf ("State key is not \"running\".\n"); free(str); return (2); } free(str); printf ("%s iid %d: stop\n", __FUNCTION__, instance_id); err = sam_stop (); if (err != CS_OK) { fprintf (stderr, "Can't stop hc. Error %d\n", err); return 2; } err = cmap_get_string(cmap_handle, key_name, &str); if (err != CS_OK) { printf ("Could not get \"state\" key: %d.\n", err); return (2); } if (strcmp(str, "stopped") != 0) { printf ("State key is not \"stopped\".\n"); free(str); return (2); } free(str); printf ("%s iid %d: sleeping 5\n", __FUNCTION__, instance_id); sleep (5); err = cmap_get_string(cmap_handle, key_name, &str); if (err != CS_OK) { printf ("Could not get \"state\" key: %d.\n", err); return (2); } if (strcmp(str, "stopped") != 0) { printf ("State key is not \"stopped\".\n"); free(str); return (2); } free(str); printf ("%s iid %d: start 2\n", __FUNCTION__, instance_id); err = sam_start (); if (err != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", err); return 2; } err = cmap_get_string(cmap_handle, key_name, &str); if (err != CS_OK) { printf ("Could not get \"state\" key: %d.\n", err); return (2); } if (strcmp(str, "running") != 0) { printf ("State key is not \"running\".\n"); free(str); return (2); } free(str); if (test_n == 2) { printf ("%s iid %d: sleeping 5. Should be killed\n", __FUNCTION__, instance_id); sleep (5); return (2); } else { printf ("%s iid %d: Test HC\n", __FUNCTION__, instance_id); err = sam_hc_send (); if (err != CS_OK) { fprintf (stderr, "Can't send hc. Error %d\n", err); return 2; } snprintf(key_name, CMAP_KEYNAME_MAXLEN, "resources.process.%d.last_updated", pid); err = cmap_get_uint64(cmap_handle, key_name, &tstamp1); if (err != CS_OK) { printf ("Could not get \"last_updated\" key: %d.\n", err); return (2); } printf ("%s iid %d: Sleep 1\n", __FUNCTION__, instance_id); sleep (1); err = sam_hc_send (); if (err != CS_OK) { fprintf (stderr, "Can't send hc. Error %d\n", err); return 2; } sleep (1); err = cmap_get_uint64(cmap_handle, key_name, &tstamp2); if (err != CS_OK) { printf ("Could not get \"last_updated\" key: %d.\n", err); return (2); } msec_diff = (tstamp2 - tstamp1)/CS_TIME_NS_IN_MSEC; if (msec_diff < 500 || msec_diff > 2000) { printf ("Difference %d is not within <500, 2000> interval.\n", msec_diff); return (2); } printf ("%s iid %d: stop 2\n", __FUNCTION__, instance_id); err = sam_stop (); if (err != CS_OK) { fprintf (stderr, "Can't stop hc. Error %d\n", err); return 2; } snprintf(key_name, CMAP_KEYNAME_MAXLEN, "resources.process.%d.state", pid); err = cmap_get_string(cmap_handle, key_name, &str); if (err != CS_OK) { printf ("Could not get \"state\" key: %d.\n", err); return (2); } if (strcmp(str, "stopped") != 0) { printf ("State key is not \"stopped\".\n"); free(str); return (2); } free(str); printf ("%s iid %d: exiting\n", __FUNCTION__, instance_id); return (0); } } if (test_n == 3) { printf ("%s Testing if status is failed\n", __FUNCTION__); /* * Previous should be FAILED */ snprintf(key_name, CMAP_KEYNAME_MAXLEN, "resources.process.%d.state", pid); err = cmap_get_string(cmap_handle, key_name, &str); if (err != CS_OK) { printf ("Could not get \"state\" key: %d.\n", err); return (2); } if (strcmp(str, "failed") != 0) { printf ("State key is not \"failed\".\n"); free(str); return (2); } free(str); return (0); } return (2); } /* * Test cmap integration + restart policy */ static int test9 (pid_t pid, pid_t old_pid, int test_n) { cs_error_t err; cmap_handle_t cmap_handle; unsigned int instance_id; char *str; char key_name[CMAP_KEYNAME_MAXLEN]; err = cmap_initialize (&cmap_handle); if (err != CS_OK) { printf ("Could not initialize Cluster Map API instance error %d. Test skipped\n", err); return (1); } printf ("%s test %d\n", __FUNCTION__, test_n); if (test_n == 1) { printf ("%s: initialize\n", __FUNCTION__); err = sam_initialize (2000, SAM_RECOVERY_POLICY_RESTART | SAM_RECOVERY_POLICY_CMAP); if (err != CS_OK) { fprintf (stderr, "Can't initialize SAM API. Error %d\n", err); return 2; } printf ("%s: register\n", __FUNCTION__); err = sam_register (&instance_id); if (err != CS_OK) { fprintf (stderr, "Can't register. Error %d\n", err); return 2; } printf ("%s: iid %d\n", __FUNCTION__, instance_id); if (instance_id < 3) { snprintf(key_name, CMAP_KEYNAME_MAXLEN, "resources.process.%d.recovery", pid); err = cmap_get_string(cmap_handle, key_name, &str); if (err != CS_OK) { printf ("Could not get \"recovery\" key: %d.\n", err); return (2); } if (strcmp(str, "restart") != 0) { printf ("Recovery key \"%s\" is not \"restart\".\n", str); free(str); return (2); } free(str); snprintf(key_name, CMAP_KEYNAME_MAXLEN, "resources.process.%d.state", pid); err = cmap_get_string(cmap_handle, key_name, &str); if (err != CS_OK) { printf ("Could not get \"state\" key: %d.\n", err); return (2); } if (strcmp(str, "stopped") != 0) { printf ("State key is not \"stopped\".\n"); free(str); return (2); } free(str); printf ("%s iid %d: start\n", __FUNCTION__, instance_id); err = sam_start (); if (err != CS_OK) { fprintf (stderr, "Can't start hc. Error %d\n", err); return 2; } err = cmap_get_string(cmap_handle, key_name, &str); if (err != CS_OK) { printf ("Could not get \"state\" key: %d.\n", err); return (2); } if (strcmp(str, "running") != 0) { printf ("State key is not \"running\".\n"); free(str); return (2); } free(str); printf ("%s iid %d: waiting for kill\n", __FUNCTION__, instance_id); sleep (10); return (2); } if (instance_id == 3) { printf ("%s iid %d: mark failed\n", __FUNCTION__, instance_id); err = sam_mark_failed (); if (err != CS_OK) { fprintf (stderr, "Can't mark failed. Error %d\n", err); return 2; } sleep (10); return (2); } return (2); } if (test_n == 2) { printf ("%s Testing if status is failed\n", __FUNCTION__); /* * Previous should be FAILED */ snprintf(key_name, CMAP_KEYNAME_MAXLEN, "resources.process.%d.state", pid); err = cmap_get_string(cmap_handle, key_name, &str); if (err != CS_OK) { printf ("Could not get \"state\" key: %d.\n", err); return (2); } if (strcmp(str, "failed") != 0) { printf ("State key is not \"failed\".\n"); free(str); return (2); } free(str); return (0); } return (2); } int main(int argc, char *argv[]) { pid_t pid, old_pid; int err; int stat; int all_passed = 1; int no_skipped = 0; pid = fork (); if (pid == -1) { fprintf (stderr, "Can't fork\n"); return 1; } if (pid == 0) { err = test1 (); sam_finalize (); return err; } waitpid (pid, &stat, 0); fprintf (stderr, "test1 %s\n", (WEXITSTATUS (stat) == 0 ? "passed" : "failed")); if (WEXITSTATUS (stat) != 0) all_passed = 0; pid = fork (); if (pid == -1) { fprintf (stderr, "Can't fork\n"); return 1; } if (pid == 0) { err = test2 (); sam_finalize (); return (err); } waitpid (pid, &stat, 0); fprintf (stderr, "test2 %s\n", (WEXITSTATUS (stat) == 0 ? "passed" : "failed")); if (WEXITSTATUS (stat) != 0) all_passed = 0; pid = fork (); if (pid == -1) { fprintf (stderr, "Can't fork\n"); return 1; } if (pid == 0) { err = test3 (); sam_finalize (); return (err); } waitpid (pid, &stat, 0); fprintf (stderr, "test3 %s\n", (WEXITSTATUS (stat) == 0 ? "passed" : "failed")); if (WEXITSTATUS (stat) != 0) all_passed = 0; pid = fork (); if (pid == -1) { fprintf (stderr, "Can't fork\n"); return 1; } if (pid == 0) { err = test4 (); sam_finalize (); return (err); } waitpid (pid, &stat, 0); fprintf (stderr, "test4 %s\n", (WEXITSTATUS (stat) == 0 ? "passed" : "failed")); if (WEXITSTATUS (stat) != 0) all_passed = 0; pid = fork (); if (pid == -1) { fprintf (stderr, "Can't fork\n"); return 1; } if (pid == 0) { err = test5 (); sam_finalize (); return (err); } waitpid (pid, &stat, 0); fprintf (stderr, "test5 %s\n", (WEXITSTATUS (stat) == 0 ? "passed" : "failed")); if (WEXITSTATUS (stat) != 0) all_passed = 0; pid = fork (); if (pid == -1) { fprintf (stderr, "Can't fork\n"); return 1; } if (pid == 0) { err = test6 (); sam_finalize (); return (err); } waitpid (pid, &stat, 0); fprintf (stderr, "test6 %s\n", (WEXITSTATUS (stat) == 0 ? "passed" : "failed")); if (WEXITSTATUS (stat) != 0) all_passed = 0; pid = fork (); if (pid == -1) { fprintf (stderr, "Can't fork\n"); return 2; } if (pid == 0) { err = test7 (); sam_finalize (); return (err); } waitpid (pid, &stat, 0); fprintf (stderr, "test7 %s\n", (WEXITSTATUS (stat) == 0 ? "passed" : (WEXITSTATUS (stat) == 1 ? "skipped" : "failed"))); if (WEXITSTATUS (stat) == 1) no_skipped++; if (WEXITSTATUS (stat) > 1) all_passed = 0; pid = fork (); if (pid == -1) { fprintf (stderr, "Can't fork\n"); return 2; } if (pid == 0) { err = test8 (getpid (), 0, 1); sam_finalize (); return (err); } waitpid (pid, &stat, 0); old_pid = pid; if (WEXITSTATUS (stat) == 0) { pid = fork (); if (pid == -1) { fprintf (stderr, "Can't fork\n"); return 2; } if (pid == 0) { err = test8 (getpid (), old_pid, 2); sam_finalize (); return (err); } waitpid (pid, &stat, 0); old_pid = pid; if (WEXITSTATUS (stat) == 0) { pid = fork (); if (pid == -1) { fprintf (stderr, "Can't fork\n"); return 2; } if (pid == 0) { err = test8 (old_pid, 0, 3); sam_finalize (); return (err); } waitpid (pid, &stat, 0); } } fprintf (stderr, "test8 %s\n", (WEXITSTATUS (stat) == 0 ? "passed" : (WEXITSTATUS (stat) == 1 ? "skipped" : "failed"))); if (WEXITSTATUS (stat) == 1) no_skipped++; if (WEXITSTATUS (stat) > 1) all_passed = 0; pid = fork (); if (pid == -1) { fprintf (stderr, "Can't fork\n"); return 2; } if (pid == 0) { err = test9 (getpid (), 0, 1); sam_finalize (); return (err); } waitpid (pid, &stat, 0); old_pid = pid; if (WEXITSTATUS (stat) == 0) { pid = fork (); if (pid == -1) { fprintf (stderr, "Can't fork\n"); return 2; } if (pid == 0) { err = test9 (old_pid, 0, 2); sam_finalize (); return (err); } waitpid (pid, &stat, 0); } fprintf (stderr, "test9 %s\n", (WEXITSTATUS (stat) == 0 ? "passed" : (WEXITSTATUS (stat) == 1 ? "skipped" : "failed"))); if (WEXITSTATUS (stat) == 1) no_skipped++; if (WEXITSTATUS (stat) > 1) all_passed = 0; if (all_passed) fprintf (stderr, "All tests passed (%d skipped)\n", no_skipped); return (all_passed ? 0 : 1); }