feat/add_eventbus (#9)

Co-authored-by: tqcq <99722391+tqcq@users.noreply.github.com> Reviewed-on: #9
2024-01-19 04:51:24 +00:00 · 2024-01-19 04:51:24 +00:00 · 925efe8abe
commit 925efe8abe
parent 30f46d994f
8 changed files with 949 additions and 16 deletions
--- a/3party/eventbus/include/detail/leftright.h
+++ b/3party/eventbus/include/detail/leftright.h
@ -0,0 +1,388 @@
 #pragma once
 #include <algorithm>
 #include <array>
 #include <atomic>
 #include <cassert>
 #include <cstdint>
 #include <mutex>
 #include <thread>
 #include <type_traits>
 #ifndef MPM_LEFTRIGHT_CACHE_LINE_SIZE
 #define MPM_LEFTRIGHT_CACHE_LINE_SIZE 64
 #endif
 namespace mpm {
 //! \defgroup Concepts
 //! Concept is a term that describes a named set of requirements for a type.
 //! \defgroup ReaderRegistry
 //! \ingroup Concepts
 //! \{
 //!
 //! Keeps track of active readers such that it can efficiently
 //! indicate whether there are any active readers when queried.
 //!
 //! \par Extends
 //! DefaultConstructible
 //!
 //! \par Requirements
 //! Given:\n
 //! R, an implementation of the ReaderRegistry concept \n
 //! r, an instance of R
 //!
 //! |Expression  | Requirements                                             | Return type  |
 //! |:-----------|:---------------------------------------------------------|:-------------|
 //! | R()        | R is default constructible.                              | R            |
 //! | r.arrive() | Notes the arival of a reader. Wait-free and noexcept.    | void         |
 //! | r.depart() | Notes the departure of a reader. Wait-free and noexcept. | void         |
 //! | r.empty()  | const and noexcept.    | true if there are no readers; false otherwise. |
 //! \}
 struct in_place_t {};
 constexpr in_place_t in_place{};
 //! Wrap any single-threaded datastructure with Left-Right
 //! concurrency control
 //!
 //! Left-Right concurrency allows wait-free population-oblivious reads
 //! and blocking writes. Writers never block readers.
 //!
 //! Instances of this class maintain two full copies of the underlying
 //! datastructure and all modifications are performed twice. Consequently,
 //! uses of this class should be limited to small amounts of data where
 //! the number of reads dominates the number of writes.
 //!
 //! Left-Right concurrency control is described in depth in
 //!   A. Correia and P. Ramalhete. Left-Right: A Concurrency Control
 //!   Technique with Wait-Free Population Oblivious Reads
 template<typename T, typename ReaderRegistry>
 class basic_leftright {
    static_assert(noexcept(std::declval<ReaderRegistry>().arrive()),
                  "ReaderRegistry::arrive() must be noexcept");
    static_assert(noexcept(std::declval<ReaderRegistry>().depart()),
                  "ReaderRegistry::depart() must be noexcept");
    static_assert(noexcept(std::declval<const ReaderRegistry>().empty()),
                  "ReaderRegistry::empty() must be noexcept");
 public:
    using value_type = T;
    using reference = value_type &;
    using const_reference = const value_type &;
    basic_leftright() = default;
    //! Construct the two underlying instances of T
    //! by moving a seed instance
    basic_leftright(T &&seed) noexcept(
        std::is_nothrow_copy_constructible<T>::value
        && std::is_nothrow_move_constructible<T>::value);
    //! Construct the two underlying instances of T
    //! by copying a seed instance
    basic_leftright(const value_type &seed) noexcept(
        std::is_nothrow_copy_constructible<T>::value);
    //! Construct the two underlying instances of T in place, forwarding
    //! the args after the mpm::in_place tag
    template<typename... Args>
    basic_leftright(in_place_t, Args &&...) noexcept(
        std::is_nothrow_copy_constructible<T>::value
        && std::is_nothrow_constructible<T, Args...>::value);
    //! \internal
    //!  Need a use-case for these. It seems that you would never want to
    //!  move/copy/swap the full leftright instance but rather apply those
    //!  operations to the encapsulated instance, in which case the relevant
    //!  operation is accessed via modify()
    basic_leftright(const basic_leftright &other) = delete;
    basic_leftright(basic_leftright &&other) = delete;
    basic_leftright &operator=(const basic_leftright &rhs) = delete;
    basic_leftright &operator=(basic_leftright &&rhs) = delete;
    void swap(basic_leftright &other) noexcept = delete;
    //! Modify the state of the managed datastructure
    //!
    //! Blocks/is-blocked-by other concurrent writers; does not
    //! block concurrent readers
    //!
    //! This function requires that execution of the supplied functor
    //! be noexcept.
    //!
    //! The function passed will be executed twice and *must*
    //! result in the exact same mutation operation being applied
    //! in both cases. For example it would be incorrect to supply
    //! a function here that inserted a random number into the
    //! underlying datastructure if said random number were calculated
    //! for each invocation (i.e. each invocation would insert a
    //! different value).
    //!
    //! \throws std::system_error on failure to lock internal mutex
    //!
    //! \internal I wanted the declaration to be as below so that this
    //!           function doesn't even exist for non-noexcept functors,
    //!           but g++ has not yet implemented noexcept mangling
    //!           as of version 5.2.1. Instead we just static_assert the
    //!           noexcept-ness of the functor in the body of the function
    //!
    //! template <typename F>
    //! auto modify(F f)
    //!     -> typename std::enable_if<noexcept(f(std::declval<T&>())),
    //!             typename std::result_of<F(T&)>::type>::type;
    template<typename F>
    typename std::result_of<F(T &)>::type modify(F f);
    //! Observe the state of the managed datastructure
    //!
    //! Always wait-free provided ReaderRegistry::arrive() and
    //! ReaderRegistry::depart() are truly wait-free
    //!
    //! \throws Whatever the provided functor throws and nothing else
    template<typename F>
    typename std::result_of<F(const T &)>::type observe(F f) const
        noexcept(noexcept(f(std::declval<const T &>())));
 private:
    class scoped_read_indication {
    public:
        scoped_read_indication(ReaderRegistry &rr) noexcept;
        ~scoped_read_indication() noexcept;
    private:
        ReaderRegistry &m_reg;
    };
    template<typename Lock>
    void toggle_reader_registry(Lock &l) noexcept;
    enum lr { read_left, read_right };
    mutable std::array<ReaderRegistry, 2> m_reader_registries;
    std::atomic_size_t m_registry_index{0};
    std::atomic<lr> m_leftright{read_left};
    T m_left alignas(MPM_LEFTRIGHT_CACHE_LINE_SIZE);
    T m_right alignas(MPM_LEFTRIGHT_CACHE_LINE_SIZE);
    std::mutex m_writemutex;
 };
 //! Simple implementation of ReaderRegistry concept
 //!
 //! This implemtation is wait-free but readers will contend
 //! on a single cache line due to the use of a shared counter.
 //!
 //! \concept{ReaderRegistry}
 class alignas(MPM_LEFTRIGHT_CACHE_LINE_SIZE) atomic_reader_registry {
 public:
    void arrive() noexcept;
    void depart() noexcept;
    bool empty() const noexcept;
 private:
    std::atomic_uint_fast32_t m_count{0};
 };
 //! Distributed implementation of ReaderRegistry
 //!
 //! Uses an array of N counters (suitably padded) and hashes reader
 //! thread ids to indices into said array so that concurrent reader
 //! registration can be made unlikely to contend. The likelihood
 //! of a collision is dependent on the number of concurrent readers
 //! relative to N.
 //!
 //! arrive() and depart() will perform better if N is a power of two.
 //!
 //! \concept{ReaderRegistry}
 template<std::size_t N, typename Hasher = std::hash<std::thread::id>>
 class alignas(MPM_LEFTRIGHT_CACHE_LINE_SIZE)
    distributed_atomic_reader_registry {
 public:
    void arrive() noexcept;
    void depart() noexcept;
    bool empty() const noexcept;
 private:
    class alignas(MPM_LEFTRIGHT_CACHE_LINE_SIZE) counter {
    public:
        void incr() noexcept;
        void decr() noexcept;
        std::uint_fast32_t relaxed_read() const noexcept;
    private:
        std::atomic_uint_fast32_t m_value{0};
    };
    std::array<counter, N> m_counters{};
 };
 //! Default leftright uses the simpler reader registry; prefer
 //! distributed_atomic_reader_registry when reads are highly contended
 template<typename T>
 using leftright = basic_leftright<T, atomic_reader_registry>;
 #ifndef DOCS
 template<typename T, typename R>
 basic_leftright<T, R>::basic_leftright(T &&seed) noexcept(
    std::is_nothrow_copy_constructible<T>::value
    && std::is_nothrow_move_constructible<T>::value)
    : m_left(std::move(seed)),
      m_right(m_left)
 {}
 template<typename T, typename R>
 basic_leftright<T, R>::basic_leftright(const T &seed) noexcept(
    std::is_nothrow_copy_constructible<T>::value)
    : m_left(seed),
      m_right(seed)
 {}
 template<typename T, typename R>
 template<typename... Args>
 basic_leftright<T, R>::basic_leftright(in_place_t, Args &&...args) noexcept(
    std::is_nothrow_copy_constructible<T>::value
    && std::is_nothrow_constructible<T, Args...>::value)
    : m_left(std::forward<Args>(args)...),
      m_right(m_left)
 {}
 template<typename T, typename R>
 template<typename F>
 typename std::result_of<F(const T &)>::type
 basic_leftright<T, R>::observe(F f) const
    noexcept(noexcept(f(std::declval<const T &>())))
 {
    std::size_t idx = m_registry_index.load(std::memory_order_acquire);
    scoped_read_indication sri(m_reader_registries[idx]);
    return read_left == m_leftright.load(std::memory_order_acquire)
        ? f(m_left)
        : f(m_right);
 }
 template<typename T, typename R>
 template<typename F>
 typename std::result_of<F(T &)>::type
 basic_leftright<T, R>::modify(F f)
 {
    static_assert(noexcept(f(std::declval<T &>())),
                  "Modify functor must be noexcept");
    std::unique_lock<std::mutex> xlock(m_writemutex);
    if (read_left == m_leftright.load(std::memory_order_relaxed)) {
        f(m_right);
        m_leftright.store(read_right, std::memory_order_release);
        toggle_reader_registry(xlock);
        return f(m_left);
    } else {
        f(m_left);
        m_leftright.store(read_left, std::memory_order_release);
        toggle_reader_registry(xlock);
        return f(m_right);
    }
 }
 template<typename T, typename R>
 template<typename Lock>
 void
 basic_leftright<T, R>::toggle_reader_registry(Lock &l) noexcept
 {
    assert(l);
    const std::size_t current =
        m_registry_index.load(std::memory_order_acquire);
    const std::size_t next = (current + 1) & 0x1;
    while (!m_reader_registries[next].empty()) { std::this_thread::yield(); }
    m_registry_index.store(next, std::memory_order_release);
    while (!m_reader_registries[current].empty()) { std::this_thread::yield(); }
 }
 template<typename T, typename R>
 basic_leftright<T, R>::scoped_read_indication::scoped_read_indication(
    R &r) noexcept
    : m_reg(r)
 {
    m_reg.arrive();
 }
 template<typename T, typename R>
 basic_leftright<T,
                R>::scoped_read_indication::~scoped_read_indication() noexcept
 {
    m_reg.depart();
 }
 inline void
 atomic_reader_registry::arrive() noexcept
 {
    m_count.fetch_add(1, std::memory_order_acq_rel);
 }
 inline void
 atomic_reader_registry::depart() noexcept
 {
    m_count.fetch_sub(1, std::memory_order_acq_rel);
 }
 inline bool
 atomic_reader_registry::empty() const noexcept
 {
    return 0 == m_count.load(std::memory_order_acquire);
 }
 template<std::size_t N, typename Hasher>
 void
 distributed_atomic_reader_registry<N, Hasher>::arrive() noexcept
 {
    std::size_t index = Hasher()(std::this_thread::get_id()) % N;
    m_counters[index].incr();
 }
 template<std::size_t N, typename Hasher>
 void
 distributed_atomic_reader_registry<N, Hasher>::depart() noexcept
 {
    std::size_t index = Hasher()(std::this_thread::get_id()) % N;
    m_counters[index].decr();
 }
 template<std::size_t N, typename Hasher>
 bool
 distributed_atomic_reader_registry<N, Hasher>::empty() const noexcept
 {
    bool retval =
        std::none_of(begin(m_counters), end(m_counters),
                     [](const counter &ctr) { return ctr.relaxed_read(); });
    std::atomic_thread_fence(std::memory_order_acquire);
    return retval;
 }
 template<typename std::size_t N, typename H>
 void
 distributed_atomic_reader_registry<N, H>::counter::incr() noexcept
 {
    (void) m_value.fetch_add(1, std::memory_order_acq_rel);
 }
 template<typename std::size_t N, typename H>
 void
 distributed_atomic_reader_registry<N, H>::counter::decr() noexcept
 {
    (void) m_value.fetch_sub(1, std::memory_order_acq_rel);
 }
 template<typename std::size_t N, typename H>
 std::uint_fast32_t
 distributed_atomic_reader_registry<N, H>::counter::relaxed_read() const noexcept
 {
    return m_value.load(std::memory_order_relaxed);
 }
 #endif
 }// namespace mpm
--- a/3party/eventbus/include/detail/typelist.h
+++ b/3party/eventbus/include/detail/typelist.h
@ -0,0 +1,49 @@
 #pragma once
 namespace mpm {
 namespace detail {
 //! A type used to indicate an empty typelist tail. I.e. the end marker
 //! of a typelist.
 struct null_t {};
 //! Typelist a la [Alexandrescu](http://www.drdobbs.com/generic-programmingtypelists-and-applica/184403813)
 template<typename Head, typename Tail = null_t>
 struct typelist {
    //! The first element, a non-typelist by convention
    using head = Head;
    //! The second element, can be another typelist
    using tail = Tail;
 };
 template<typename F, typename TL>
 struct for_each_helper {
    void operator()(F f) const
    {
        f.template operator()<typename TL::head>();
        for_each_helper<F, typename TL::tail>()(f);
    }
 };
 template<typename F>
 struct for_each_helper<F, null_t> {
    void operator()(const F &) {}
 };
 //! Iterate over a typelist at runtime.
 //! The supplied functor, f, is invoked for each element in the typlist TL
 //!
 //! \tparam TL A typelist
 //! \tparam F A FunctionObject
 //! \param f A functor that will be called as f.template operator()\<T>()
 //!          where T is an element in TL. This functor will be invoked once
 //!          for each element of TL
 //! \relates typelist
 template<typename TL, typename F>
 void
 for_each_type(const F &f)
 {
    for_each_helper<F, TL>()(f);
 }
 }// namespace detail
 }// namespace mpm
--- a/3party/eventbus/include/enable_polymorphic_dispatch.h
+++ b/3party/eventbus/include/enable_polymorphic_dispatch.h
@ -0,0 +1,41 @@
 #pragma once
 #include "detail/typelist.h"
 namespace mpm {
 namespace detail {
 /// root class for polymorphic event hierarchies
 class event {
 protected:
    //don't dispatch as this type - it's an internal
    //implementation detail
    using dispatch_as = null_t;
    virtual ~event() {}
 };
 /// forward decl from eventbus.h
 template<typename E>
 struct dispatch_typelist;
 }// namespace detail
 //! Publicly inherit from this class to obtain polymorphic
 //! event delivery.
 template<typename T, typename Base = detail::event>
 class enable_polymorphic_dispatch : public Base {
 protected:
    // \internal
    // Couldn't use a typelist based on std::tuple here because
    // std::tuple_cat won't work with an incomplete type, and the
    // derived event types are incomplete when decltype(tuple_cat)
    // would be used
 #ifdef DOCS
    using dispatch_as = implementation - defined;
 #else
    template<typename E>
    friend class detail::dispatch_typelist;
    using dispatch_as = detail::typelist<T, typename Base::dispatch_as>;
 #endif
 };
 }// namespace mpm
--- a/3party/eventbus/include/eventbus.h
+++ b/3party/eventbus/include/eventbus.h
@ -0,0 +1,433 @@
 #pragma once
 #include "enable_polymorphic_dispatch.h"
 #include "detail/typelist.h"
 #include <memory>
 #include "detail/leftright.h"
 #include <typeindex>
 #include <unordered_map>
 #include <utility>
 //! The mpm namespace
 namespace mpm {
 //! \defgroup Concepts
 //! Concept is a term that describes a named set of requirements for a type
 //! \defgroup Event
 //! \ingroup Concepts
 //! \{
 //!
 //! An instance of any C++ object type. That is, anything but a function,
 //! reference, or void type
 //!
 //! \par Requirements
 //! Given:\n
 //! E, an implementation of the Event concept
 //!
 //! |Expression                       | Requirements             | Return type        |
 //! |:--------------------------------|:-------------------------|:-------------------|
 //! |std::is_object<E>::value == true | E must be an object type | bool, must be true |
 //! \}
 //! \defgroup EventHandler
 //! \ingroup Concepts
 //! \{
 //!
 //! A Callable that can be invoked to handle an instance of Event.
 //! Callable's INVOKE operation must be noexcept.
 //!
 //! \par Extends
 //! Callable
 //!
 //! \par Requirements
 //! Given:\n
 //! E an implementation of the Event concept,
 //! e and instance of E,
 //! H an implementation of the EventHandler concept handling events of type E,
 //! h an instance of H
 //!
 //! |Expression                      | Requirements           |
 //! |:-------------------------------|:-----------------------|
 //! |h(e)                            | well-formed            |
 //! |noexcept(h(e)) == true          | h(e) must be noexcept  |
 //! \}
 namespace detail {
 //! Adapts an instance of the Event concept into the
 //! class hierarchy rooted at mpm::detail::event
 template<typename Event>
 class adapted_event : public detail::event {
 public:
    using dispatch_as = detail::typelist<Event>;
    adapted_event(const Event &event) : m_event{event} {}
    operator const Event &() const { return m_event; }
 private:
    const Event &m_event;
 };
 //! Holds the subscriber event type and the handler instance
 //! in a type-erased manner so that they can be put into a
 //! homogeneous container (e.g. the std::unordered_multimap as below)
 class subscription {
 public:
    using id_t = std::intptr_t;
    template<typename E, typename H, typename Alloc>
    subscription(const H &handler, const Alloc &alloc, E *)
        : m_self{std::allocate_shared<model<E, H>>(alloc, handler)}
    {}
    void deliver(const event &e) { m_self->deliver(e); }
    id_t id() const { return reinterpret_cast<std::intptr_t>(m_self.get()); }
 private:
    struct concept
    {
        virtual ~concept(){};
        virtual void deliver(const event &e) = 0;
    };
    // base template for events that extend detail::event (i.e. for
    // polymorphic dispatchable events). These can be safely
    // static_cast to the subscribed event type
    template<typename E, typename H, typename Enable = void>
    struct model : concept {
        explicit model(H h) : handler(std::move(h)) {}
        void deliver(const event &e) final
        {
            handler(static_cast<const E &>(e));
        }
        H handler;
    };
    // Specialization for events that do not use
    // enable_polymorphic_dispatch. The diffence is that we static_cast
    // to adapted_event<E>.
    template<typename E, typename H>
    struct model<E,
                 H,
                 typename std::enable_if<
                     !std::is_base_of<detail::event, E>::value>::type>
        : concept {
        explicit model(H h) : handler(std::move(h)) {}
        void deliver(const event &e) final
        {
            handler(static_cast<const adapted_event<E> &>(e));
        }
        H handler;
    };
    std::shared_ptr<concept> m_self;
 };
 struct cookie {
    cookie() = default;
    cookie(subscription::id_t _id, std::type_index _ti) : id(_id), ti(_ti) {}
    subscription::id_t id = 0;
    std::type_index ti = typeid(std::nullptr_t);
 };
 //! Extract a dispatch typelist for an event supplying a dispatch_as
 //! typedef. If the supplied event type is not in the head position of
 //! the dispatch_as typelist then it is prepended to said list
 template<typename E>
 struct dispatch_typelist {
    // todo C++14 can be std::conditional_t
    // most derived type goes first
    using type = typename std::conditional<
        std::is_same<E, typename E::dispatch_as::head>::value,
        typename E::dispatch_as,
        detail::typelist<E, typename E::dispatch_as>>::type;
 };
 template<typename SubsMap>
 struct deliver {
    deliver(const event &e, const SubsMap &subs) : m_subs{subs}, m_event{e} {}
    template<typename T>
    void operator()()
    {
        auto handlers = m_subs.equal_range(std::type_index(typeid(T)));
        for (auto pos = handlers.first; pos != handlers.second; ++pos) {
            const_cast<subscription &>(pos->second).deliver(m_event);
        }
    }
    const SubsMap &m_subs;
    const event &m_event;
 };
 // not meant to be used as a virtual base class - nothing should
 // destruct via this type
 class unsubscribable {
 public:
    virtual void unsubscribe(const cookie &c) = 0;
 protected:
    ~unsubscribable() {}
 };
 }// namespace detail
 //! A small POD type representing a subscription
 using cookie = detail::cookie;
 //! Accepts events from publishers and delivers them to subscribers
 template<typename Allocator>
 class basic_eventbus : public detail::unsubscribable {
 public:
    //! The type of the Allocator used by this eventbus
    using allocator_type = Allocator;
    //! Delegates to basic_eventbus(allocator_type) using
    //! default construction for the allocator_type instance.
    basic_eventbus();
    //! Constructs an instance using the supplied allocator_type.
    explicit basic_eventbus(allocator_type alloc);
 #ifdef DOCS
    //! Publish an instance of E.
    //!
    //! The event instance will be delivered either as only type E or
    //! if E has been defined with mpm::enable_polymorphic_dispatch it
    //! will be delivered as every type in its inheritance chain.
    //!
    //! \tparam E An instance of the Event concept
    //! \param event The event to publish
    //! \returns void
    template<typename E>
    void publish(const E &event) noexcept;
 #else
    template<typename E>
    typename std::enable_if<std::is_base_of<detail::event, E>::value>::type
    publish(const E &event) noexcept;
    template<typename E>
    typename std::enable_if<!std::is_base_of<detail::event, E>::value>::type
    publish(const E &event) noexcept;
 #endif
    //! Subscribe to instances of Event
    //!
    //! The supplied handler will be invoked when events of type Event
    //! are published or when classes derived from Event that have chosen
    //! to enable polymorphic dispatch are published.
    //!
    //! \tparam Event The type for which to subscribe
    //! \tparam EventHandler an instance of the EventHandler concept
    //! \param handler An instance of EventHandler
    //! \returns A cookie which will allow for this handler to be
    //!         unsubscribed later via basic_eventbus::unsubscribe
    template<typename Event, typename EventHandler>
    cookie subscribe(const EventHandler &handler);
    //! Unsubscribes an event handler
    //!
    //! \param c A cookie obtained when basic_eventbus::subscribe was called
    //! \returns void
    void unsubscribe(const cookie &c) override;
 private:
    using subscriptions =
        leftright<std::unordered_multimap<std::type_index,
                                          detail::subscription,
                                          std::hash<std::type_index>,
                                          std::equal_to<std::type_index>,
                                          allocator_type>>;
    allocator_type m_alloc;
    subscriptions m_subscriptions;
 };
 //! Default eventbus uses std::allocator<char>
 using eventbus = basic_eventbus<std::allocator<char>>;
 template<typename A>
 basic_eventbus<A>::basic_eventbus() : basic_eventbus(allocator_type())
 {}
 template<typename A>
 basic_eventbus<A>::basic_eventbus(allocator_type alloc)
    : m_alloc{std::move(alloc)},
      m_subscriptions{in_place, alloc}
 {}
 #ifndef DOCS
 template<typename A>
 template<typename Event>
 typename std::enable_if<std::is_base_of<detail::event, Event>::value>::type
 basic_eventbus<A>::publish(const Event &event) noexcept
 {
    using types = typename detail::dispatch_typelist<Event>::type;
    m_subscriptions.observe([&](typename subscriptions::const_reference subs) {
        detail::for_each_type<types>(
            detail::deliver<decltype(subs)>{event, subs});
    });
 }
 template<typename A>
 template<typename Event>
 typename std::enable_if<!std::is_base_of<detail::event, Event>::value>::type
 basic_eventbus<A>::publish(const Event &event) noexcept
 {
    publish(detail::adapted_event<Event>{event});
 }
 #endif
 template<typename A>
 template<typename Event, typename EventHandler>
 cookie
 basic_eventbus<A>::subscribe(const EventHandler &handler)
 {
    static_assert(std::is_object<Event>::value, "Events must be object types");
    static_assert(noexcept(handler(std::declval<const Event &>())),
                  "Need noexcept handler for Event");
    Event *ptr{};
    detail::subscription sub{handler, m_alloc, ptr};
    return m_subscriptions.modify(
        [&](typename subscriptions::reference subs) noexcept {
            auto idx = std::type_index(typeid(Event));
            subs.emplace(idx, sub);
            return cookie{sub.id(), idx};
        });
 }
 template<typename A>
 void
 basic_eventbus<A>::unsubscribe(const cookie &c)
 {
    m_subscriptions.modify(
        [=](typename subscriptions::reference subs) noexcept {
            auto range = subs.equal_range(c.ti);
            for (auto pos = range.first; pos != range.second; ++pos) {
                if (pos->second.id() == c.id) {
                    subs.erase(pos);
                    return;
                }
            }
        });
 }
 //! An RAII type for eventbus subscriptions
 //!
 //! This type will ensure that the encapsulated eventbus subscription
 //! is released when it goes out of scope.
 //!
 //! \tparam Event the type of event for which this subscription subscribes
 template<typename Event>
 class scoped_subscription {
 public:
    using event_type = Event;
    //! Construct a scoped_subscription not managing any subscription
    scoped_subscription() = default;
    //! Move from another scoped_subscription.
    scoped_subscription(scoped_subscription &&other) noexcept
        : m_ebus{other.m_ebus},
          m_cookie{other.m_cookie}
    {
        other.m_ebus = nullptr;
    }
    //! Copying a scoped_subscription is prohibited
    scoped_subscription(const scoped_subscription &) = delete;
    //! Move-assign from another scoped_subscription
    scoped_subscription &operator=(scoped_subscription &&other) noexcept
    {
        reset();
        m_ebus = other.m_ebus;
        m_cookie = other.m_cookie;
        other.m_ebus = nullptr;
    }
    void swap(scoped_subscription &other) noexcept
    {
        using std::swap;
        swap(m_ebus, other.m_ebus);
        swap(m_cookie, other.m_cookie);
    }
    //! Initializes a subscription that will be usubscribed when
    //! this object goes out of scope.
    //!
    //! Subscription is constructed with ebus.subscribe<Event>(h)
    //!
    //! \tparam Alloc The allocator type of the event bus supplied
    //! \tparam Handler the type of the handler supplied
    //! \param ebus An instance of basic_eventbus to use for subscribing
    //! \param h An instance of an event handler
    template<typename Alloc, typename Handler>
    scoped_subscription(basic_eventbus<Alloc> &ebus, const Handler &h)
        : m_ebus{&ebus},
          m_cookie{ebus.template subscribe<event_type>(h)}
    {}
    //! Initializes a subscription that will be usubscribed when
    //! this object goes out of scope.
    //!
    //! Subscription is constructed with ebus.subscribe<Event>(h). If
    //! this object currently manages a subscription, that subscription
    //! will be cleared as though reset() had been called.
    //!
    //! \tparam Alloc The allocator type of the event bus supplied
    //! \tparam Handler the type of the handler supplied
    //! \param ebus An instance of basic_eventbus to use for subscribing
    //! \param h An instance of an event handler
    template<typename Alloc, typename Handler>
    void assign(basic_eventbus<Alloc> &ebus, const Handler &h)
    {
        reset();
        m_ebus = &ebus;
        m_cookie = ebus.template subscribe<event_type>(h);
    }
    //! Unsubscribes this objects managed subscription if one exists
    ~scoped_subscription() { reset(); }
    //! Unsubscribes this objects managed subscription if one exists
    //! \returns void
    void reset()
    {
        if (m_ebus) { m_ebus->unsubscribe(m_cookie); }
    }
 private:
    friend void swap(scoped_subscription &lhs, scoped_subscription &rhs)
    {
        lhs.swap(rhs);
    }
    detail::unsubscribable *m_ebus = nullptr;//non-owning
    cookie m_cookie{};
 };
 }// namespace mpm
 namespace ulib {
 template<typename T, typename Base = mpm::detail::event>
 using enable_polymorphic_dispatch = mpm::enable_polymorphic_dispatch<T, Base>;
 // using eventbus = mpm::basic_eventbus<std::allocator<char>>;
 using eventbus = mpm::basic_eventbus<std::allocator<
    std::pair<const std::type_index, mpm::detail::subscription>>>;
 template<typename EventType>
 using scoped_subscription = mpm::scoped_subscription<EventType>;
 }// namespace ulib
--- a/3party/nonstd/optional.h
+++ b/3party/nonstd/optional.h
@ -2500,7 +2500,7 @@ template<typename T>
 using hash = std::hash<tl::optional<T>>;
 // if <= C++14
-#if __cplusplus < 201703L
+// #if __cplusplus < 201703L
 template<typename T>
 using optional = tl::optional<T>;
@ -2530,7 +2530,7 @@ make_optional(std::initializer_list<U> il, Args &&...args)
 }
 constexpr tl::nullopt_t nullopt{tl::nullopt};
-#endif
+// #endif
 }// namespace ulib
 #endif
--- a/CMakeLists.txt
+++ b/CMakeLists.txt
@ -16,17 +16,17 @@ option(ULIB_SHARED_LIB "Build shared library" OFF)
 option(ULIB_BUILD_EXAMPLES "Build examples" OFF)
 if(NOT CMAKE_BUILD_TYPE)
-    set(CMAKE_BUILD_TYPE "Release")
+  set(CMAKE_BUILD_TYPE "Release")
-    # set stripped
+  # set stripped
-    set(CMAKE_CXX_FLAGS_RELEASE "${CMAKE_CXX_FLAGS_RELEASE} -s")
+  set(CMAKE_CXX_FLAGS_RELEASE "${CMAKE_CXX_FLAGS_RELEASE} -s")
 endif()
 # add -static-libgcc and -static-libstdc++ to link flags
 set(CMAKE_POSITION_INDEPENDENT_CODE ON)
 if(ULIB_SHARED_LIB)
-    add_library(${PROJECT_NAME} SHARED "")
+  add_library(${PROJECT_NAME} SHARED "")
 else()
-    add_library(${PROJECT_NAME} STATIC "" src/ulib/system/timer.cpp
+  add_library(${PROJECT_NAME} STATIC "" src/ulib/system/timer.cpp
                                     src/ulib/system/timer.h)
 endif()
 target_sources(
@ -63,10 +63,10 @@ list(APPEND CMAKE_MODULE_PATH "${CMAKE_CURRENT_SOURCE_DIR}/cmake")
 # CMP0063
 if(POLICY CMP0063)
-    cmake_policy(SET CMP0063 NEW)
+  cmake_policy(SET CMP0063 NEW)
 endif()
 if(POLICY CMP0048)
-    cmake_policy(SET CMP0048 NEW)
+  cmake_policy(SET CMP0048 NEW)
 endif()
 set(FMT_USE_CPP11
@ -97,6 +97,7 @@ target_compile_definitions(${PROJECT_NAME} PRIVATE ULIB_LIBRARY_IMPL)
 target_include_directories(
  ${PROJECT_NAME}
  PUBLIC 3party/bnflite
         3party/eventbus/include
         3party/inja
         3party/mongoose
         3party/nlohmann
@ -109,14 +110,14 @@ target_include_directories(
 install(TARGETS ${PROJECT_NAME} DESTINATION lib)
 if(ULIB_BUILD_TESTS)
-    enable_testing()
+  enable_testing()
-    set(GTEST_LANG_CXX11 OFF)
+  set(GTEST_LANG_CXX11 OFF)
-    set(GTEST_HAS_TR1_TUPLE OFF)
+  set(GTEST_HAS_TR1_TUPLE OFF)
-    set(GTEST_USE_OWN_TR1_TUPLE ON)
+  set(GTEST_USE_OWN_TR1_TUPLE ON)
-    add_subdirectory(3party/googletest)
+  add_subdirectory(3party/googletest)
-    add_subdirectory(tests)
+  add_subdirectory(tests)
 endif()
 if(ULIB_BUILD_EXAMPLES)
-    add_subdirectory(examples)
+  add_subdirectory(examples)
 endif()
--- a/tests/3party/eventbus/eventbus_unittest.cpp
+++ b/tests/3party/eventbus/eventbus_unittest.cpp
@ -0,0 +1,20 @@
 #include <gtest/gtest.h>
 #include <eventbus.h>
 TEST(EventBus, BaseTest)
 {
    struct Event {
        int x;
    };
    ulib::eventbus bus;
    int calls = 0;
    ulib::scoped_subscription<Event> ss(bus, [&](const Event &e) noexcept {
        EXPECT_EQ(calls, e.x);
        ++calls;
    });
    bus.publish(Event{0});
    EXPECT_EQ(calls, 1);
    bus.publish(Event{1});
    EXPECT_EQ(calls, 2);
 }
--- a/tests/CMakeLists.txt
+++ b/tests/CMakeLists.txt
@ -13,6 +13,7 @@ add_executable(
  ulib/system/thread_unittest.cpp
  ulib/system/thread_pool_unittest.cpp
  ulib/system/timer_unittest.cpp
  3party/eventbus/eventbus_unittest.cpp
  3party/inja/inja_unittest.cpp
  3party/optional/optional_unittest.cpp
  3party/sqlpp11/sqlpp11_unittest.cpp