valib/bhshmq.git

			@@ -19,18 +19,29 @@
			#include "util.h"
			#include <atomic>

			using namespace bhome::msg;
			using namespace bhome_msg;

			namespace
			{
			typedef std::atomic<uint64_t> Number;

			void Assign(Number &a, const Number &b) { a.store(b.load()); }
			struct MsgStatus {

			Number nrequest_;
			Number nfailed_;
			Number nreply_;
			Number nserved_;
			MsgStatus() :
			nrequest_(0), nreply_(0), nserved_(0) {}
			MsgStatus &operator=(const MsgStatus &a)
			{
			Assign(nrequest_, a.nrequest_);
			Assign(nserved_, a.nserved_);
			Assign(nreply_, a.nreply_);
			Assign(nfailed_, a.nfailed_);
			return *this;
			}
			};

			MsgStatus &Status()
			@@ -55,7 +66,7 @@
			const int proc_id_len,
			const void *data,
			const int data_len,
			BHServerCallbackTag *tag)
			void *src)
			{
			// printf("ServerProc: ");
			// DEFER1(printf("\n"););
			@@ -65,7 +76,7 @@
			reply.set_data(" reply: " + request.data());
			std::string s(reply.SerializeAsString());
			// printf("%s", reply.data().c_str());
			BHServerCallbackReply(tag, s.data(), s.size());
			BHSendReply(src, s.data(), s.size());
			++Status().nserved_;
			}
			}
			@@ -85,6 +96,175 @@
			// printf("client Recv reply : %s\n", reply.data().c_str());
			}

			class TLMutex
			{
			// typedef boost::interprocess::interprocess_mutex MutexT;
			typedef CasMutex MutexT;
			// typedef std::mutex MutexT;
			typedef std::chrono::steady_clock Clock;
			typedef Clock::duration Duration;
			static Duration Now() { return Clock::now().time_since_epoch(); }

			const Duration limit_;
			std::atomic<Duration> last_lock_time_;
			MutexT mutex_;

			public:
			struct Status {
			int64_t nlock_ = 0;
			int64_t nupdate_time_fail = 0;
			int64_t nfail = 0;
			int64_t nexcept = 0;
			};
			Status st_;

			explicit TLMutex(Duration limit) :
			limit_(limit) {}
			TLMutex() :
			TLMutex(std::chrono::seconds(1)) {}
			~TLMutex() { static_assert(std::is_pod<Duration>::value); }
			bool try_lock()
			{
			if (mutex_.try_lock()) {
			auto old_time = last_lock_time_.load();
			if (Now() - old_time > limit_) {
			return last_lock_time_.compare_exchange_strong(old_time, Now());
			} else {
			last_lock_time_.store(Now());
			return true;
			}
			} else {
			auto old_time = last_lock_time_.load();
			if (Now() - old_time > limit_) {
			return last_lock_time_.compare_exchange_strong(old_time, Now());
			} else {
			return false;
			}
			}
			}
			void lock()
			{
			int n = 0;
			while (!try_lock()) {
			n++;
			std::this_thread::yield();
			}
			st_.nlock_ += n;
			}
			void unlock() { mutex_.unlock(); }
			};

			namespace
			{
			typedef int64_t Offset;
			Offset Addr(void *ptr) { return reinterpret_cast<Offset>(ptr); }
			void Ptr(const Offset offset) { return reinterpret_cast<void >(offset); }
			} // namespace

			BOOST_AUTO_TEST_CASE(MutexTest)
			{
			SharedMemory &shm = TestShm();
			MsgI::BindShm(shm);

			void *base_ptr = shm.get_address();
			auto PrintPtr = [&](void *p) {
			printf("addr: %ld, ptr: %p, offset: %ld\n", Addr(p), p, Addr(p) - Addr(base_ptr));
			};

			printf("base");
			PrintPtr(base_ptr);

			MsgI msg;
			msg.Make("string data");
			for (int i = 0; i < 10; ++i) {
			int n = msg.AddRef();
			printf("add %d ref: %d\n", i, n);
			}
			for (int i = 0; i < 10; ++i) {
			int n = msg.Release();
			printf("release %d, ref : %d\n", i, n);
			}
			std::this_thread::sleep_for(1s);
			msg.Release();

			const std::string mtx_name("test_mutex");
			const std::string int_name("test_int");
			auto mtx = shm.find_or_construct<Mutex>(mtx_name.c_str())();
			auto pi = shm.find_or_construct<int>(int_name.c_str())(100);

			printf("mutetx ");
			PrintPtr(mtx);
			printf("int ");
			PrintPtr(pi);

			typedef std::chrono::steady_clock Clock;
			auto Now = []() { return Clock::now().time_since_epoch(); };
			if (pi) {
			auto old = *pi;
			printf("int : %d, add1: %d\n", old, ++*pi);
			}

			{
			boost::timer::auto_cpu_timer timer;
			printf("test time: ");
			TLMutex mutex;
			// CasMutex mutex;
			auto Lock = [&]() {
			for (int i = 0; i < 1000 * 100; ++i) {
			mutex.lock();
			mutex.unlock();
			}
			};
			std::thread t1(Lock), t2(Lock);
			t1.join();
			t2.join();
			printf("mutex nlock: %ld, update time error: %ld, normal fail: %ld, error wait: %ld\n",
			mutex.st_.nlock_,
			mutex.st_.nupdate_time_fail,
			mutex.st_.nfail,
			mutex.st_.nexcept);
			}

			auto MSFromNow = [](const int ms) {
			using namespace boost::posix_time;
			ptime cur = boost::posix_time::microsec_clock::universal_time();
			return cur + millisec(ms);
			};

			auto TryLock = [&]() {
			if (mtx->try_lock()) {
			printf("try_lock ok\n");
			return true;
			} else {
			printf("try_lock failed\n");
			return false;
			}
			};
			auto Unlock = [&]() {
			mtx->unlock();
			printf("unlocked\n");
			};

			if (mtx) {
			printf("mtx exists\n");
			if (TryLock()) {
			auto op = [&]() {
			if (TryLock()) {
			Unlock();
			}
			};
			op();
			std::thread t(op);
			t.join();
			// Unlock();
			} else {
			// mtx->unlock();
			}
			} else {
			printf("mtx not exists\n");
			}
			}

			BOOST_AUTO_TEST_CASE(ApiTest)
			{
			auto max_time = std::chrono::steady_clock::time_point::max();
			@@ -102,7 +282,7 @@
			printf("maxsec: %ld\n", CountSeconds(max_time));

			bool reg = false;
			for (int i = 0; i < 10 && !reg; ++i) {
			for (int i = 0; i < 3 && !reg; ++i) {
			ProcInfo proc;
			proc.set_proc_id("demo_client");
			proc.set_public_info("public info of demo_client. etc...");
			@@ -114,6 +294,9 @@

			BHFree(reply, reply_len);
			Sleep(1s);
			}
			if (!reg) {
			return;
			}

			const std::string topic_ = "topic_";
			@@ -151,7 +334,7 @@
			for (int i = 0; i < 1; ++i) {
			MsgPublish pub;
			pub.set_topic(topic_ + std::to_string(i));
			pub.set_data("pub_data_" + std::string(1024 * 1024, 'a'));
			pub.set_data("pub_data_" + std::string(1024 * 1, 'a'));
			std::string s(pub.SerializeAsString());
			BHPublish(s.data(), s.size(), 0);
			// Sleep(1s);
			@@ -166,36 +349,50 @@
			std::string s(req.SerializeAsString());
			void *msg_id = 0;
			int len = 0;
			bool r = BHAsyncRequest(s.data(), s.size(), 0, 0);
			// Sleep(10ms, false);
			std::string dest(BHAddress().SerializeAsString());
			bool r = BHAsyncRequest(dest.data(), dest.size(), s.data(), s.size(), 0, 0);
			DEFER1(BHFree(msg_id, len););
			if (r) {
			++Status().nrequest_;
			} else {
			printf("request topic : %s\n", r ? "ok" : "failed");
			++Status().nfailed_;
			static std::atomic<int64_t> last(0);
			auto now = NowSec();
			if (last.exchange(now) < now) {
			int ec = 0;
			std::string msg;
			GetLastError(ec, msg);
			printf("request topic error --------- : %s\n", msg.c_str());
			}
			}
			}
			};
			auto showStatus = [](std::atomic<bool> *run) {
			int64_t last = 0;
			MsgStatus last;
			while (*run) {
			auto &st = Status();
			std::this_thread::sleep_for(1s);
			int cur = st.nreply_.load();
			printf("nreq: %8ld, nsrv: %8ld, nreply: %8ld, speed %8ld\n", st.nrequest_.load(), st.nserved_.load(), cur, cur - last);
			last = cur;
			Sleep(1s, false);
			printf("nreq: %8ld, spd %8ld \| failed: %8ld \| nsrv: %8ld, spd %8ld \| nreply: %8ld, spd %8ld\n",
			st.nrequest_.load(), st.nrequest_ - last.nrequest_,
			st.nfailed_.load(),
			st.nserved_.load(), st.nserved_ - last.nserved_,
			st.nreply_.load(), st.nreply_ - last.nreply_);
			last = st;
			}
			};
			auto hb = [](std::atomic<bool> *run) {
			while (*run) {
			BHHeartBeatEasy(0);
			std::this_thread::sleep_for(1s);
			Sleep(1s, false);
			bool r = BHHeartbeatEasy(1000);
			printf("heartbeat: %s\n", r ? "ok" : "failed");
			}
			};
			std::atomic<bool> run(true);
			ThreadManager threads;
			boost::timer::auto_cpu_timer timer;
			threads.Launch(hb, &run);
			// threads.Launch(showStatus, &run);
			threads.Launch(showStatus, &run);
			int ncli = 10;
			const uint64_t nreq = 1000 * 100;
			for (int i = 0; i < ncli; ++i) {
			@@ -204,8 +401,8 @@

			int same = 0;
			int64_t last = 0;
			while (last < nreq * ncli && same < 3) {
			Sleep(1s);
			while (last < nreq * ncli && same < 2) {
			Sleep(1s, false);
			auto cur = Status().nreply_.load();
			if (last == cur) {
			++same;