valib/bhshmq.git

			@@ -19,89 +19,175 @@
			#ifndef SHM_6CHO6D6C
			#define SHM_6CHO6D6C

			#include <boost/noncopyable.hpp>
			#include <boost/uuid/uuid.hpp>
			#include <atomic>
			#include <boost/interprocess/managed_shared_memory.hpp>
			#include <boost/interprocess/sync/interprocess_mutex.hpp>
			#include <boost/interprocess/sync/interprocess_condition.hpp>
			#include <boost/interprocess/sync/interprocess_mutex.hpp>
			#include <boost/interprocess/sync/scoped_lock.hpp>
			#include <boost/noncopyable.hpp>
			#include <chrono>
			#include <thread>

			namespace bhome_shm {
			namespace bhome_shm
			{

			using namespace boost::interprocess;

			typedef managed_shared_memory mshm_t;
			typedef interprocess_mutex Mutex;

			class CasMutex
			{
			std::atomic<bool> flag_;
			bool cas(bool expected, bool new_val) { return flag_.compare_exchange_strong(expected, new_val); }

			public:
			CasMutex() :
			flag_(false) {}
			bool try_lock() { return cas(false, true); }
			void lock()
			{
			while (!try_lock()) { std::this_thread::yield(); }
			}
			void unlock() { cas(true, false); }
			};

			class MutexWithTimeLimit
			{
			typedef boost::interprocess::interprocess_mutex MutexT;
			// typedef CasMutex 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:
			typedef MutexT::internal_mutex_type internal_mutex_type;
			const internal_mutex_type &internal_mutex() const { return mutex_.internal_mutex(); }
			internal_mutex_type &internal_mutex() { return mutex_.internal_mutex(); }

			explicit MutexWithTimeLimit(Duration limit) :
			limit_(limit) {}
			MutexWithTimeLimit() :
			MutexWithTimeLimit(std::chrono::seconds(1)) {}
			~MutexWithTimeLimit() { static_assert(std::is_pod<Duration>::value); }
			bool try_lock();
			void lock();
			void unlock();
			};

			// typedef boost::interprocess::interprocess_mutex Mutex;
			typedef MutexWithTimeLimit Mutex;
			typedef scoped_lock<Mutex> Guard;
			typedef interprocess_condition Cond;

			class SharedMemory : public mshm_t
			{
			std::string name_;
			std::string name_;

			static permissions AllowAll() {
			permissions perm;
			perm.set_unrestricted();
			return perm;
			}
			void Swap(SharedMemory &a);
			static permissions AllowAll()
			{
			permissions perm;
			perm.set_unrestricted();
			return perm;
			}
			void Swap(SharedMemory &a);

			public:
			static bool Remove(const std::string &name) {
			return shared_memory_object::remove(name.c_str());
			}
			SharedMemory(const std::string &name, const uint64_t size);
			~SharedMemory();
			std::string name() const { return name_; }
			bool Remove() { return Remove(name()); }
			static bool Remove(const std::string &name) { return shared_memory_object::remove(name.c_str()); }

			void *Alloc(const size_t size) { return allocate(size, std::nothrow); }
			void Dealloc(void *p) { if(p) { deallocate(p); } }
			template<class T> void Dealloc(offset_ptr<T> ptr) { return Dealloc(ptr.get()); }
			SharedMemory(const std::string &name, const uint64_t size);
			~SharedMemory();
			std::string name() const { return name_; }
			bool Remove() { return Remove(name()); }
			template <class T, class... Params>
			T *FindOrCreate(const std::string &name, Params &&...params)
			{
			return find_or_construct<T>(name.c_str(), std::nothrow)(std::forward<decltype(params)>(params)...);
			}
			template <class T, class... Params>
			T *Create(const std::string &name, Params &&...params)
			{
			return construct<T>(name.c_str(), std::nothrow)(std::forward<decltype(params)>(params)...);
			}
			void *Alloc(const size_t size) { return allocate(size, std::nothrow); }
			void Dealloc(void *p)
			{
			if (p) { deallocate(p); }
			}
			template <class T>
			void Dealloc(offset_ptr<T> ptr) { return Dealloc(ptr.get()); }

			template <class T, class ...Params> T * New(Params const&...params) { return construct<T>(anonymous_instance, std::nothrow)(params...); }
			template <class T> void Delete(T *p) { if (p) { destroy_ptr<T>(p); }; }
			template <class T> void Delete(offset_ptr<T> p) { Delete(p.get()); }

			template <class T, class... Params>
			T *New(Params &&...params) { return construct<T>(anonymous_instance, std::nothrow)(std::forward<decltype(params)>(params)...); }
			template <class T>
			void Delete(T *p)
			{
			if (p) { destroy_ptr<T>(p); };
			}
			template <class T>
			void Delete(offset_ptr<T> p) { Delete(p.get()); }
			template <class T>
			T *Find(const std::string &name) { return find<T>(name.c_str()).first; }
			};

			template <class D>
			using Allocator = allocator<D, SharedMemory::segment_manager>;
			template <class D>
			using Deleter = deleter<D, SharedMemory::segment_manager>;
			template <class D>
			using SharedPtr = shared_ptr<D, Allocator<void>, Deleter<D>>;

			// ShmObject manages an object in shared memory, but ShmObject itself is not in shared memory.
			// works like a smart pointer of an object in shared memory.
			// TODO handshake with center, and can be removed if killed.
			template <class T>
			class ShmObject : private boost::noncopyable {
			static std::string ObjName(const std::string &name) { return "obj" + name; }
			protected:
			typedef T Data;
			typedef SharedMemory ShmType;
			private:
			ShmType &shm_;
			std::string name_;
			Data *pdata_ = nullptr;
			class ShmObject : private boost::noncopyable
			{
			static std::string ObjName(const std::string &name) { return "obj" + name; }

			bool IsOk() const { return pdata_; }
			protected:
			ShmType &shm() const { return shm_; }
			public:
			template <class...Params>
			ShmObject(ShmType &segment, const std::string &name, Params&&...t):
			shm_(segment), name_(name)
			{
			pdata_ = shm_.find_or_construct<Data>(ObjName(name_).c_str(), std::nothrow)(t...);
			if (!IsOk()) {
			throw("Error: Not enough memory, can not allocate \"" + name_ + "\"");
			}
			}
			Data *find(const std::string &name) { return shm_.find<Data>(ObjName(name).c_str()).first; }
			virtual ~ShmObject() {}
			std::string name() const { return name_; }
			Data* data() { return pdata_; }
			const Data* data() const { return pdata_; }
			Data* operator->() { return data(); }
			const Data* operator->() const { return data(); }
			bool Remove() { return shm_.destroy<Data>(ObjName(name_).c_str()); }
			};
			typedef T Data;
			typedef SharedMemory ShmType;
			ShmType &shm() const { return shm_; }

			template <class D> using Allocator = allocator<D, SharedMemory::segment_manager>;
			template <class... Params>
			ShmObject(ShmType &segment, const std::string &name, Params &&...t) :
			shm_(segment), name_(name)
			{
			pdata_ = shm_.FindOrCreate<Data>(ObjName(name_), std::forward<decltype(t)>(t)...);
			if (!IsOk()) {
			throw("Error: Not enough memory, can not allocate \"" + name_ + "\"");
			}
			}
			template <class... Params>
			ShmObject(ShmType &segment, const bool create_or_else_find, const std::string &name, Params &&...t) :
			shm_(segment), name_(name)
			{
			if (create_or_else_find) {
			pdata_ = shm_.Create<Data>(ObjName(name_), std::forward<decltype(t)>(t)...);
			} else {
			pdata_ = shm_.Find<Data>(ObjName(name_));
			}
			}
			bool IsOk() const { return pdata_; }

			static bool Remove(SharedMemory &shm, const std::string &name) { return shm.destroy<Data>(ObjName(name).c_str()); }
			static Data *Find(SharedMemory &shm, const std::string &name) { return shm.Find<Data>(ObjName(name)); }
			Data *Find(const std::string &name) { return Find(shm_, ObjName(name)); }
			virtual ~ShmObject() {}
			std::string name() const { return name_; }
			Data *data() { return pdata_; }
			const Data *data() const { return pdata_; }
			Data *operator->() { return data(); }
			const Data *operator->() const { return data(); }
			bool Remove() { return Remove(shm_, name_); }

			private:
			ShmType &shm_;
			std::string name_;
			Data *pdata_ = nullptr;
			};

			} // namespace bhome_shm