/* -*- Mode: C++; tab-width: 4; c-basic-offset: 4; indent-tabs-mode: nil -*- */ /* * Copyright 2012 Couchbase, Inc. * * 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 "config.h" #include "iotests.h" #include #include #include #include "internal.h" /* vbucket_* things from lcb_t */ #include "auth-priv.h" #include #include "bucketconfig/bc_http.h" #define LOGARGS(instance, lvl) \ instance->settings, "tests-MUT", LCB_LOG_##lvl, __FILE__, __LINE__ extern "C" { static void timings_callback(lcb_t, const void *cookie, lcb_timeunit_t, lcb_U32, lcb_U32, lcb_U32, lcb_U32) { bool *bPtr = (bool *)cookie; *bPtr = true; } } TEST_F(MockUnitTest, testTimings) { lcb_t instance; HandleWrap hw; bool called = false; createConnection(hw, instance); lcb_enable_timings(instance); lcb_store_cmd_t storecmd(LCB_SET, "counter", 7, "0", 1); lcb_store_cmd_t *storecmds[] = { &storecmd }; lcb_store(instance, NULL, 1, storecmds); lcb_wait(instance); lcb_get_timings(instance, &called, timings_callback); lcb_disable_timings(instance); ASSERT_TRUE(called); } namespace { struct TimingInfo { lcb_U64 ns_start; lcb_U64 ns_end; size_t count; TimingInfo() : ns_start(-1), ns_end(-1), count(-1) {} bool operator<(const TimingInfo& other) const { return other.ns_start > ns_start; } bool operator>(const TimingInfo& other) const { return ns_start > other.ns_start; } bool valid() const { return count != -1; } }; static lcb_U64 intervalToNsec(lcb_U64 interval, lcb_timeunit_t unit) { if (unit == LCB_TIMEUNIT_NSEC) { return interval; } else if (unit == LCB_TIMEUNIT_USEC) { return interval * 1000; } else if (unit == LCB_TIMEUNIT_MSEC) { return interval * 1000000; } else if (unit == LCB_TIMEUNIT_SEC) { return interval * 1000000000; } else { return -1; } } struct LcbTimings { LcbTimings() {} std::vector m_info; void load(lcb_t); void clear(); TimingInfo infoAt(hrtime_t duration, lcb_timeunit_t unit = LCB_TIMEUNIT_NSEC); size_t countAt(hrtime_t duration, lcb_timeunit_t unit = LCB_TIMEUNIT_NSEC) { return infoAt(duration, unit).count; } void dump() const; }; extern "C" { static void load_timings_callback(lcb_t, const void *cookie, lcb_timeunit_t unit, lcb_U32 min, lcb_U32 max, lcb_U32 total, lcb_U32 maxtotal) { lcb_U64 start = intervalToNsec(min, unit); lcb_U64 end = intervalToNsec(max, unit); LcbTimings *timings = (LcbTimings *)cookie; TimingInfo info; info.ns_start = start; info.ns_end = end; info.count = total; timings->m_info.push_back(info); } } // extern "C" void LcbTimings::load(lcb_t instance) { lcb_get_timings(instance, this, load_timings_callback); std::sort(m_info.begin(), m_info.end()); } TimingInfo LcbTimings::infoAt(hrtime_t duration, lcb_timeunit_t unit) { duration = intervalToNsec(duration, unit); std::vector::iterator ii; for (ii = m_info.begin(); ii != m_info.end(); ++ii) { if (ii->ns_start <= duration && ii->ns_end > duration) { return *ii; } } return TimingInfo(); } void LcbTimings::dump() const { std::vector::const_iterator ii = m_info.begin(); for (; ii != m_info.end(); ii++) { if (ii->ns_end < 1000) { printf("[%llu-%llu ns] %lu\n", ii->ns_start, ii->ns_end, ii->count); } else if (ii->ns_end < 10000000) { printf("[%llu-%llu us] %lu\n", ii->ns_start / 1000, ii->ns_end / 1000, ii->count); } else { printf("[%llu-%llu ms] %lu\n", ii->ns_start / 1000000, ii->ns_end / 1000000, ii->count); } } } } // namespace{ struct UnitInterval { lcb_U64 n; lcb_timeunit_t unit; UnitInterval(lcb_U64 n, lcb_timeunit_t unit) : n(n), unit(unit) {} }; static void addTiming(lcb_t instance, const UnitInterval& interval) { hrtime_t n = intervalToNsec(interval.n, interval.unit); lcb_histogram_record(instance->kv_timings, n); } TEST_F(MockUnitTest, testTimingsEx) { lcb_t instance; HandleWrap hw; createConnection(hw, instance); lcb_disable_timings(instance); lcb_enable_timings(instance); std::vector intervals; intervals.push_back(UnitInterval(1, LCB_TIMEUNIT_NSEC)); intervals.push_back(UnitInterval(250, LCB_TIMEUNIT_NSEC)); intervals.push_back(UnitInterval(4, LCB_TIMEUNIT_USEC)); intervals.push_back(UnitInterval(32, LCB_TIMEUNIT_USEC)); intervals.push_back(UnitInterval(942, LCB_TIMEUNIT_USEC)); intervals.push_back(UnitInterval(1243, LCB_TIMEUNIT_USEC)); intervals.push_back(UnitInterval(1732, LCB_TIMEUNIT_USEC)); intervals.push_back(UnitInterval(5630, LCB_TIMEUNIT_USEC)); intervals.push_back(UnitInterval(42, LCB_TIMEUNIT_MSEC)); intervals.push_back(UnitInterval(434, LCB_TIMEUNIT_MSEC)); intervals.push_back(UnitInterval(8234, LCB_TIMEUNIT_MSEC)); intervals.push_back(UnitInterval(1294, LCB_TIMEUNIT_MSEC)); intervals.push_back(UnitInterval(48, LCB_TIMEUNIT_SEC)); for (size_t ii = 0; ii < intervals.size(); ++ii) { addTiming(instance, intervals[ii]); } // Ensure they all exist, at least. Currently we bundle everything LcbTimings timings; timings.load(instance); //timings.dump(); // Measuring in < us ASSERT_EQ(2, timings.countAt(50, LCB_TIMEUNIT_NSEC)); ASSERT_EQ(1, timings.countAt(4, LCB_TIMEUNIT_USEC)); ASSERT_EQ(1, timings.countAt(30, LCB_TIMEUNIT_USEC)); ASSERT_EQ(-1, timings.countAt(900, LCB_TIMEUNIT_USEC)); ASSERT_EQ(1, timings.countAt(940, LCB_TIMEUNIT_USEC)); ASSERT_EQ(1, timings.countAt(1200, LCB_TIMEUNIT_USEC)); ASSERT_EQ(1, timings.countAt(1250, LCB_TIMEUNIT_USEC)); ASSERT_EQ(1, timings.countAt(5600, LCB_TIMEUNIT_USEC)); ASSERT_EQ(1, timings.countAt(40, LCB_TIMEUNIT_MSEC)); ASSERT_EQ(1, timings.countAt(430, LCB_TIMEUNIT_MSEC)); ASSERT_EQ(1, timings.countAt(1, LCB_TIMEUNIT_SEC)); ASSERT_EQ(1, timings.countAt(8, LCB_TIMEUNIT_SEC)); ASSERT_EQ(1, timings.countAt(93, LCB_TIMEUNIT_SEC)); } struct async_ctx { int count; lcbio_pTABLE table; }; extern "C" { static void dtor_callback(const void *cookie) { async_ctx *ctx = (async_ctx *)cookie; ctx->count++; IOT_STOP(ctx->table); } } TEST_F(MockUnitTest, testAsyncDestroy) { lcb_t instance; createConnection(instance); lcbio_pTABLE iot = instance->iotable; lcb_settings *settings = instance->settings; storeKey(instance, "foo", "bar"); // Now destroy the instance async_ctx ctx; ctx.count = 0; ctx.table = iot; lcb_set_destroy_callback(instance, dtor_callback); lcb_destroy_async(instance, &ctx); lcb_settings_ref(settings); lcbio_table_ref(iot); lcb_run_loop(instance); lcb_settings_unref(settings); lcbio_table_unref(iot); ASSERT_EQ(1, ctx.count); } TEST_F(MockUnitTest, testGetHostInfo) { lcb_t instance; createConnection(instance); lcb_config_transport_t tx; const char *hoststr = lcb_get_node(instance, LCB_NODE_HTCONFIG, 0); ASSERT_FALSE(hoststr == NULL); hoststr = lcb_get_node(instance, LCB_NODE_HTCONFIG_CONNECTED, 0); lcb_error_t err = lcb_cntl(instance, LCB_CNTL_GET, LCB_CNTL_CONFIG_TRANSPORT, &tx); ASSERT_EQ(LCB_SUCCESS, err); if (tx == LCB_CONFIG_TRANSPORT_HTTP) { ASSERT_FALSE(hoststr == NULL); hoststr = lcb_get_node(instance, LCB_NODE_HTCONFIG_CONNECTED, 99); ASSERT_FALSE(hoststr == NULL); } else { if (hoststr) { printf("%s\n", hoststr); } ASSERT_TRUE(hoststr == NULL); } // Get any data node using std::map; using std::string; map smap; // Ensure we only get unique nodes for (size_t ii = 0; ii < lcb_get_num_nodes(instance); ii++) { const char *cur = lcb_get_node(instance, LCB_NODE_DATA, ii); ASSERT_FALSE(cur == NULL); ASSERT_FALSE(smap[cur]); smap[cur] = true; } lcb_destroy(instance); // Try with no connection err = lcb_create(&instance, NULL); ASSERT_EQ(LCB_SUCCESS, err); hoststr = lcb_get_node(instance, LCB_NODE_HTCONFIG_CONNECTED, 0); ASSERT_TRUE(NULL == hoststr); hoststr = lcb_get_node(instance, LCB_NODE_HTCONFIG, 0); ASSERT_TRUE(NULL == hoststr); // These older API functions are special as they should never return NULL hoststr = lcb_get_host(instance); ASSERT_FALSE(hoststr == NULL); ASSERT_STREQ("localhost", hoststr); hoststr = lcb_get_port(instance); ASSERT_FALSE(hoststr == NULL); ASSERT_STREQ("8091", hoststr); lcb_destroy(instance); } TEST_F(MockUnitTest, testEmptyKeys) { lcb_t instance; HandleWrap hw; createConnection(hw, instance); union { lcb_CMDGET get; lcb_CMDSTORE store; lcb_CMDCOUNTER counter; lcb_CMDENDURE endure; lcb_CMDOBSERVE observe; lcb_CMDTOUCH touch; lcb_CMDUNLOCK unlock; lcb_CMDGETREPLICA rget; lcb_CMDBASE base; lcb_CMDSTATS stats; } u; memset(&u, 0, sizeof u); lcb_sched_enter(instance); ASSERT_EQ(LCB_EMPTY_KEY, lcb_get3(instance, NULL, &u.get)); ASSERT_EQ(LCB_EMPTY_KEY, lcb_store3(instance, NULL, &u.store)); ASSERT_EQ(LCB_EMPTY_KEY, lcb_counter3(instance, NULL, &u.counter)); ASSERT_EQ(LCB_EMPTY_KEY, lcb_touch3(instance, NULL, &u.touch)); ASSERT_EQ(LCB_EMPTY_KEY, lcb_unlock3(instance, NULL, &u.unlock)); ASSERT_EQ(LCB_EMPTY_KEY, lcb_rget3(instance, NULL, &u.rget)); // Observe and such lcb_MULTICMD_CTX *ctx = lcb_observe3_ctxnew(instance); ASSERT_EQ(LCB_EMPTY_KEY, ctx->addcmd(ctx, (lcb_CMDBASE*)&u.observe)); ctx->fail(ctx); lcb_durability_opts_t dopts; memset(&dopts, 0, sizeof dopts); dopts.v.v0.persist_to = 1; ctx = lcb_endure3_ctxnew(instance, &dopts, NULL); ASSERT_TRUE(ctx != NULL); ASSERT_EQ(LCB_EMPTY_KEY, ctx->addcmd(ctx, (lcb_CMDBASE*)&u.endure)); ctx->fail(ctx); ASSERT_EQ(LCB_SUCCESS, lcb_stats3(instance, NULL, &u.stats)); lcb_sched_fail(instance); } template static bool ctlSet(lcb_t instance, int setting, T val) { lcb_error_t err = lcb_cntl(instance, LCB_CNTL_SET, setting, &val); return err == LCB_SUCCESS; } template<> bool ctlSet(lcb_t instance, int setting, const char *val) { return lcb_cntl(instance, LCB_CNTL_SET, setting, (void*)val) == LCB_SUCCESS; } template static T ctlGet(lcb_t instance, int setting) { T tmp; lcb_error_t err = lcb_cntl(instance, LCB_CNTL_GET, setting, &tmp); EXPECT_EQ(LCB_SUCCESS, err); return tmp; } template static void ctlGetSet(lcb_t instance, int setting, T val) { EXPECT_TRUE(ctlSet(instance, setting, val)); EXPECT_EQ(val, ctlGet(instance, setting)); } template <> void ctlGetSet(lcb_t instance, int setting, const char *val) { EXPECT_TRUE(ctlSet(instance, setting, val)); EXPECT_STREQ(val, ctlGet(instance, setting)); } static bool ctlSetInt(lcb_t instance, int setting, int val) { return ctlSet(instance, setting, val); } static int ctlGetInt(lcb_t instance, int setting) { return ctlGet(instance, setting); } static bool ctlSetU32(lcb_t instance, int setting, lcb_U32 val) { return ctlSet(instance, setting, val); } static lcb_U32 ctlGetU32(lcb_t instance, int setting) { return ctlGet(instance, setting); } TEST_F(MockUnitTest, testCtls) { lcb_t instance; HandleWrap hw; lcb_error_t err; createConnection(hw, instance); ctlGetSet(instance, LCB_CNTL_OP_TIMEOUT, UINT_MAX); ctlGetSet(instance, LCB_CNTL_VIEW_TIMEOUT, UINT_MAX); ASSERT_EQ(LCB_TYPE_BUCKET, ctlGet(instance, LCB_CNTL_HANDLETYPE)); ASSERT_FALSE(ctlSet(instance, LCB_CNTL_HANDLETYPE, LCB_TYPE_BUCKET)); lcbvb_CONFIG *cfg = ctlGet(instance, LCB_CNTL_VBCONFIG); // Do we have a way to verify this? ASSERT_FALSE(cfg == NULL); ASSERT_GT(cfg->nsrv, 0); lcb_io_opt_t io = ctlGet(instance, LCB_CNTL_IOPS); ASSERT_TRUE(io == instance->getIOT()->p); // Try to set it? ASSERT_FALSE(ctlSet(instance, LCB_CNTL_IOPS, (lcb_io_opt_t)"Hello")); // Map a key lcb_cntl_vbinfo_t vbi = { 0 }; vbi.v.v0.key = "123"; vbi.v.v0.nkey = 3; err = lcb_cntl(instance, LCB_CNTL_GET, LCB_CNTL_VBMAP, &vbi); ASSERT_EQ(LCB_SUCCESS, err); // Try to modify it? err = lcb_cntl(instance, LCB_CNTL_SET, LCB_CNTL_VBMAP, &vbi); ASSERT_NE(LCB_SUCCESS, err); ctlGetSet(instance, LCB_CNTL_IP6POLICY, LCB_IPV6_DISABLED); ctlGetSet(instance, LCB_CNTL_IP6POLICY, LCB_IPV6_ONLY); ctlGetSet(instance, LCB_CNTL_CONFERRTHRESH, UINT_MAX); ctlGetSet(instance, LCB_CNTL_DURABILITY_TIMEOUT, UINT_MAX); ctlGetSet(instance, LCB_CNTL_DURABILITY_INTERVAL, UINT_MAX); ctlGetSet(instance, LCB_CNTL_HTTP_TIMEOUT, UINT_MAX); ctlGetSet(instance, LCB_CNTL_IOPS_DLOPEN_DEBUG, 55); ctlGetSet(instance, LCB_CNTL_CONFIGURATION_TIMEOUT, UINT_MAX); ctlGetSet(instance, LCB_CNTL_RANDOMIZE_BOOTSTRAP_HOSTS, 1); ctlGetSet(instance, LCB_CNTL_RANDOMIZE_BOOTSTRAP_HOSTS, 0); ASSERT_EQ(0, ctlGetInt(instance, LCB_CNTL_CONFIG_CACHE_LOADED)); ASSERT_FALSE(ctlSetInt(instance, LCB_CNTL_CONFIG_CACHE_LOADED, 99)); ctlGetSet(instance, LCB_CNTL_FORCE_SASL_MECH, "SECRET"); ctlGetSet(instance, LCB_CNTL_MAX_REDIRECTS, SHRT_MAX); ctlGetSet(instance, LCB_CNTL_MAX_REDIRECTS, -1); ctlGetSet(instance, LCB_CNTL_MAX_REDIRECTS, 0); // LCB_CNTL_LOGGER handled in other tests ctlGetSet(instance, LCB_CNTL_CONFDELAY_THRESH, UINT_MAX); // CONFIG_TRANSPORT. Test that we shouldn't be able to set it ASSERT_FALSE(ctlSet( instance, LCB_CNTL_CONFIG_TRANSPORT, LCB_CONFIG_TRANSPORT_LIST_END)); ctlGetSet(instance, LCB_CNTL_CONFIG_NODE_TIMEOUT, UINT_MAX); ctlGetSet(instance, LCB_CNTL_HTCONFIG_IDLE_TIMEOUT, UINT_MAX); ASSERT_FALSE(ctlSet(instance, LCB_CNTL_CHANGESET, "deadbeef")); ASSERT_FALSE(ctlGet(instance, LCB_CNTL_CHANGESET) == NULL); ctlGetSet(instance, LCB_CNTL_CONFIGCACHE, "/foo/bar/baz"); ASSERT_FALSE(ctlSetInt(instance, LCB_CNTL_SSL_MODE, 90)); ASSERT_GE(ctlGetInt(instance, LCB_CNTL_SSL_MODE), 0); ASSERT_FALSE(ctlSet(instance, LCB_CNTL_SSL_CACERT, "/tmp")); lcb_U32 ro_in, ro_out; ro_in = LCB_RETRYOPT_CREATE(LCB_RETRY_ON_SOCKERR, LCB_RETRY_CMDS_GET); ASSERT_TRUE(ctlSet(instance, LCB_CNTL_RETRYMODE, ro_in)); ro_out = LCB_RETRYOPT_CREATE(LCB_RETRY_ON_SOCKERR, 0); err = lcb_cntl(instance, LCB_CNTL_GET, LCB_CNTL_RETRYMODE, &ro_out); ASSERT_EQ(LCB_SUCCESS, err); ASSERT_EQ(LCB_RETRY_CMDS_GET, LCB_RETRYOPT_GETPOLICY(ro_out)); ASSERT_EQ(LCB_SUCCESS, lcb_cntl_string(instance, "retry_policy", "topochange:get")); ro_out = LCB_RETRYOPT_CREATE(LCB_RETRY_ON_TOPOCHANGE, 0); err = lcb_cntl(instance, LCB_CNTL_GET, LCB_CNTL_RETRYMODE, &ro_out); ASSERT_EQ(LCB_RETRY_CMDS_GET, LCB_RETRYOPT_GETPOLICY(ro_out)); ctlGetSet(instance, LCB_CNTL_HTCONFIG_URLTYPE, LCB_HTCONFIG_URLTYPE_COMPAT); ctlGetSet(instance, LCB_CNTL_COMPRESSION_OPTS, LCB_COMPRESS_FORCE); ctlSetU32(instance, LCB_CNTL_CONLOGGER_LEVEL, 3); lcb_U32 tmp; err = lcb_cntl(instance, LCB_CNTL_GET, LCB_CNTL_CONLOGGER_LEVEL, &tmp); ASSERT_NE(LCB_SUCCESS, err); ctlGetSet(instance, LCB_CNTL_DETAILED_ERRCODES, 1); ctlGetSet(instance, LCB_CNTL_RETRY_INTERVAL, UINT_MAX); ctlGetSet(instance, LCB_CNTL_RETRY_BACKOFF, 3.4); ctlGetSet(instance, LCB_CNTL_HTTP_POOLSIZE, UINT_MAX); ctlGetSet(instance, LCB_CNTL_HTTP_REFRESH_CONFIG_ON_ERROR, 0); // Allow timeouts to be expressed as fractional seconds. err = lcb_cntl_string(instance, "operation_timeout", "1.0"); ASSERT_EQ(LCB_SUCCESS, err); ASSERT_EQ(1000000, ctlGet(instance, LCB_CNTL_OP_TIMEOUT)); err = lcb_cntl_string(instance, "operation_timeout", "0.255"); ASSERT_EQ(LCB_SUCCESS, err); ASSERT_EQ(255000, ctlGet(instance, LCB_CNTL_OP_TIMEOUT)); // Test default for nmv retry int itmp = ctlGetInt(instance, LCB_CNTL_RETRY_NMV_IMM); ASSERT_NE(0, itmp); err = lcb_cntl_string(instance, "retry_nmv_imm", "0"); ASSERT_EQ(LCB_SUCCESS, err); itmp = ctlGetInt(instance, LCB_CNTL_RETRY_NMV_IMM); ASSERT_EQ(0, itmp); } TEST_F(MockUnitTest, testConflictingOptions) { HandleWrap hw; lcb_t instance; createConnection(hw, instance); lcb_sched_enter(instance); const char *key = "key"; size_t nkey = 3; const char *value = "value"; size_t nvalue = 5; lcb_CMDSTORE scmd = { 0 }; scmd.operation = LCB_APPEND; scmd.exptime = 1; LCB_CMD_SET_KEY(&scmd, key, nkey); LCB_CMD_SET_VALUE(&scmd, value, nvalue); lcb_error_t err; err = lcb_store3(instance, NULL, &scmd); ASSERT_EQ(LCB_OPTIONS_CONFLICT, err); scmd.exptime = 0; scmd.flags = 99; err = lcb_store3(instance, NULL, &scmd); ASSERT_EQ(LCB_OPTIONS_CONFLICT, err); scmd.flags = 0; scmd.exptime = 0; err = lcb_store3(instance, NULL, &scmd); ASSERT_EQ(LCB_SUCCESS, err); scmd.operation = LCB_ADD; scmd.cas = 0xdeadbeef; err = lcb_store3(instance, NULL, &scmd); ASSERT_EQ(LCB_OPTIONS_CONFLICT, err); scmd.cas = 0; err = lcb_store3(instance, NULL, &scmd); ASSERT_EQ(LCB_SUCCESS, err); lcb_CMDCOUNTER ccmd = { 0 }; LCB_CMD_SET_KEY(&ccmd, key, nkey); ccmd.cas = 0xdeadbeef; err = lcb_counter3(instance, NULL, &ccmd); ASSERT_EQ(LCB_OPTIONS_CONFLICT, err); ccmd.cas = 0; err = lcb_counter3(instance, NULL, &ccmd); ASSERT_EQ(LCB_SUCCESS, err); ccmd.exptime = 10; ccmd.initial = 0; ccmd.create = 0; err = lcb_counter3(instance, NULL, &ccmd); ASSERT_EQ(LCB_OPTIONS_CONFLICT, err); ccmd.create = 1; err = lcb_counter3(instance, NULL, &ccmd); ASSERT_EQ(LCB_SUCCESS, err); lcb_CMDGET gcmd = { 0 }; LCB_CMD_SET_KEY(&gcmd, key, nkey); gcmd.cas = 0xdeadbeef; err = lcb_get3(instance, NULL, &gcmd); ASSERT_EQ(LCB_OPTIONS_CONFLICT, err); gcmd.cas = 0; err = lcb_get3(instance, NULL, &gcmd); ASSERT_EQ(LCB_SUCCESS, err); lcb_sched_fail(instance); } TEST_F(MockUnitTest, testDump) { const char *fpname; #ifdef _WIN32 fpname = "NUL:"; #else fpname = "/dev/null"; #endif FILE *fp = fopen(fpname, "w"); if (!fp) { perror(fpname); return; } // Simply try to dump the instance; HandleWrap hw; lcb_t instance; createConnection(hw, instance); std::vector keys; genDistKeys(LCBT_VBCONFIG(instance), keys); for (size_t ii = 0; ii < keys.size(); ii++) { storeKey(instance, keys[ii], keys[ii]); } lcb_dump(instance, fp, LCB_DUMP_ALL); fclose(fp); } TEST_F(MockUnitTest, testRefreshConfig) { HandleWrap hw; lcb_t instance; createConnection(hw, instance); lcb_refresh_config(instance); lcb_wait3(instance, LCB_WAIT_NOCHECK); } extern "C" { static void tickOpCb(lcb_t, int, const lcb_RESPBASE *rb) { int *p = (int *)rb->cookie; *p -= 1; EXPECT_EQ(LCB_SUCCESS, rb->rc); } } TEST_F(MockUnitTest, testTickLoop) { HandleWrap hw; lcb_t instance; lcb_error_t err; createConnection(hw, instance); const char *key = "tickKey"; const char *value = "tickValue"; lcb_install_callback3(instance, LCB_CALLBACK_STORE, tickOpCb); lcb_CMDSTORE cmd = { 0 }; cmd.operation = LCB_SET; LCB_CMD_SET_KEY(&cmd, key, strlen(key)); LCB_CMD_SET_VALUE(&cmd, value, strlen(value)); err = lcb_tick_nowait(instance); if (err == LCB_CLIENT_FEATURE_UNAVAILABLE) { fprintf(stderr, "Current event loop does not support tick!"); return; } lcb_sched_enter(instance); int counter = 0; for (int ii = 0; ii < 10; ii++) { err = lcb_store3(instance, &counter, &cmd); ASSERT_EQ(LCB_SUCCESS, err); counter++; } lcb_sched_leave(instance); while (counter) { lcb_tick_nowait(instance); } } TEST_F(MockUnitTest, testEmptyCtx) { HandleWrap hw; lcb_t instance; lcb_error_t err = LCB_SUCCESS; createConnection(hw, instance); lcb_MULTICMD_CTX *mctx; lcb_durability_opts_t duropts = { 0 }; duropts.v.v0.persist_to = 1; mctx = lcb_endure3_ctxnew(instance, &duropts, &err); ASSERT_EQ(LCB_SUCCESS, err); ASSERT_FALSE(mctx == NULL); err = mctx->done(mctx, NULL); ASSERT_NE(LCB_SUCCESS, err); mctx = lcb_observe3_ctxnew(instance); ASSERT_FALSE(mctx == NULL); err = mctx->done(mctx, NULL); ASSERT_NE(LCB_SUCCESS, err); } TEST_F(MockUnitTest, testMultiCreds) { using lcb::Authenticator; HandleWrap hw; lcb_t instance; createConnection(hw, instance); lcb_BUCKETCRED cred; cred[0] = "protected"; cred[1] = "secret"; lcb_error_t rc = lcb_cntl(instance, LCB_CNTL_SET, LCB_CNTL_BUCKET_CRED, cred); ASSERT_EQ(LCB_SUCCESS, rc); Authenticator& auth = *instance->settings->auth; lcb::Authenticator::Map::const_iterator res = auth.buckets().find("protected"); ASSERT_NE(auth.buckets().end(), res); ASSERT_EQ("secret", res->second); }